/*
* helper function that searches for a specific block device and returns
* it's busid
* dev: <major>:<minor> of the device
* busid: buffer in which the busid string will be returned
* returns 0 for successful operation and -1 in case of an error.
*/
static int find_busid_in_sysfs(char *dev, char *busid) {
DIR *blockdir, *diskdir;
struct dirent *blockde, *diskde;
int found = 0;
char namebuffer[PATH_BUFFER_LENGTH];
char *blockend, *diskend = NULL, *partend;
/* everything, including the other helper functions, works on the
* same buffer area 'namebuffer'. The pointers blockend, diskend
* and partend point to the end of the various names.
* Example:
* "/sys/block/dasda/dasda1/"
* ^ blockend
* ^ diskend
* ^ partend
*/
strcpy(namebuffer,BLOCKPATH);
blockdir = opendir(namebuffer);
if (!blockdir)
return -1;
blockend = namebuffer + strlen(namebuffer);
/* check each entry in /sys/block */
while ((blockde = readdir(blockdir))) {
diskend = append_if_directory(namebuffer, blockend, blockde);
if (!diskend)
continue;
found = check_directory(namebuffer, dev);
if (found)
break;
diskdir = opendir(namebuffer);
if (!diskdir)
continue;
/* check each entry in /sys/block/<disk name> */
while ((diskde = readdir(diskdir))) {
partend = append_if_directory(
namebuffer, diskend, diskde);
if (!partend)
continue;
found = check_directory(namebuffer, dev);
if (found)
break;
}
closedir(diskdir);
if (found)
break;
}
closedir(blockdir);
if (found) {
*diskend = 0; /* remove partition directory from name */
return extract_busid(namebuffer, busid);
} else
return -1;
}
static void
mapper_set_playlist_dir(const char *path)
{
check_directory(path);
playlist_dir = g_strdup(path);
}
int
main(int argc, char *argv[])
{
struct hooks_t hooks;
struct files_t files;
//int c;
/* TODO: Parse command line arguments */
parse_commandline(argc, argv);
/* TODO: Initialize hooks and files lists */
TAILQ_INIT(&hooks);
TAILQ_INIT(&files);
/* TODO: Load hooks */
set_hooks(&hooks);
// TODO: Continuously check directory and timestamps
//while(true){
char *timestamp = timestamp_string();
check_directory(directory, &hooks, &files, recursive,(time_t) timestamp);
sleep(1);
//}
return (EXIT_SUCCESS);
}
int main(int argc, char* argv[])
{
std::string errmsg;
if (!mooon::utils::parse_arguments(argc, argv, &errmsg))
{
fprintf(stderr, "%s\n", errmsg.c_str());
return false;
}
try
{
int ret = 0;
if (mooon::sys::CUtils::is_file(mooon::argument::sqllog->c_value()))
ret = check_file(mooon::argument::sqllog->c_value());
else
ret = check_directory(mooon::argument::sqllog->c_value());
fprintf(stdout, "lines: %d\n", sg_lines);
return ret;
}
catch (mooon::sys::CSyscallException& ex)
{
fprintf(stderr, "%s\n", ex.str().c_str());
exit(1);
}
}
char* InliningDatabase::index_file_name() {
char* name = NEW_RESOURCE_ARRAY(char, 1024);
if (!check_directory(directory())) return NULL;
strcpy(name, directory());
strcat(name, "\\index.txt");
return name;
}
krb5_boolean KRB5_LIB_FUNCTION
krb5_kuserok (krb5_context context,
krb5_principal principal,
const char *luser)
{
char *buf;
size_t buflen;
struct passwd *pwd;
krb5_error_code ret;
krb5_boolean result = FALSE;
krb5_boolean found_file = FALSE;
#ifdef POSIX_GETPWNAM_R
char pwbuf[2048];
struct passwd pw;
if(getpwnam_r(luser, &pw, pwbuf, sizeof(pwbuf), &pwd) != 0)
return FALSE;
#else
pwd = getpwnam (luser);
#endif
if (pwd == NULL)
return FALSE;
#define KLOGIN "/.k5login"
buflen = strlen(pwd->pw_dir) + sizeof(KLOGIN) + 2; /* 2 for .d */
buf = malloc(buflen);
if(buf == NULL)
return FALSE;
/* check user's ~/.k5login */
strlcpy(buf, pwd->pw_dir, buflen);
strlcat(buf, KLOGIN, buflen);
ret = check_one_file(context, buf, pwd, principal, &result);
if(ret == 0 && result == TRUE) {
free(buf);
return TRUE;
}
if(ret != ENOENT)
found_file = TRUE;
strlcat(buf, ".d", buflen);
ret = check_directory(context, buf, pwd, principal, &result);
free(buf);
if(ret == 0 && result == TRUE)
return TRUE;
if(ret != ENOENT && ret != ENOTDIR)
found_file = TRUE;
/* finally if no files exist, allow all principals matching
<localuser>@<LOCALREALM> */
if(found_file == FALSE)
return match_local_principals(context, principal, luser);
return FALSE;
}
//!
//! Validate and initialize the Eucalyptus and hook directories to use.
//!
//! @param[in] euca_dir a string containing the Eucalyptus directory to use
//! @param[in] hooks_dir a string containing the hook directory to use
//!
//! @return EUCA_OK if the operation is successful or proper error code. Known error
//! code returned include EUCA_ERROR.
//!
int init_hooks(const char *euca_dir, const char *hooks_dir)
{
assert(euca_dir);
assert(hooks_dir);
euca_strncpy(euca_path, euca_dir, sizeof(euca_path));
if (check_directory(euca_path))
return (EUCA_ERROR);
euca_strncpy(hooks_path, hooks_dir, sizeof(hooks_path));
if (check_directory(hooks_path))
return (EUCA_ERROR);
LOGINFO("using hooks directory %s\n", hooks_path);
initialized = TRUE;
return (EUCA_OK);
}
static void
mapper_set_music_dir(const char *path)
{
check_directory(path);
music_dir = strdup_chop_slash(path);
music_dir_length = strlen(music_dir);
}
int scInitConfig (void)
{
struct stat mystat;
char config [BUFSIZE];
char * s;
if (scConfigInit) {
return 0;
}
if ((sc_sem = sem_alloc (1, "eucalyptus-storage-semaphore")) == NULL) { /* TODO: use this semaphore to fix the race */
logprintfl (EUCAERROR, "failed to create and initialize a semaphore\n");
return 1;
}
/* read in configuration */
char * home = getenv (EUCALYPTUS_ENV_VAR_NAME);
if (!home) {
home = strdup(""); /* root by default */
}
snprintf(config, BUFSIZE, EUCALYPTUS_CONF_LOCATION, home);
if (stat(config, &mystat)==0) {
logprintfl (EUCAINFO, "SC is looking for configuration in %s\n", config);
if (get_conf_var(config, INSTANCE_PATH, &s)>0){
sc_instance_path = strdup (s);
free (s);
}
if (get_conf_var(config, CONFIG_NC_CACHE_SIZE, &s)>0){
cache_size_mb = atoll (s);
cache_free_mb = cache_size_mb;
free (s);
}
if (get_conf_var(config, CONFIG_NC_SWAP_SIZE, &s)>0){
swap_size_mb = atoll (s);
free (s);
}
}
snprintf(add_key_command_path, BUFSIZE, EUCALYPTUS_ADD_KEY, home, home, home);
/* we need to have valid path */
if (check_directory(sc_instance_path)) {
logprintfl (EUCAERROR, "ERROR: INSTANCE_PATH (%s) does not exist!\n", sc_instance_path);
return(1);
}
if (euca_init_cert ()) {
logprintfl (EUCAFATAL, "failed to find cryptographic certificates\n");
return 1;
}
snprintf (disk_convert_command_path, BUFSIZE, EUCALYPTUS_DISK_CONVERT, home, home);
scConfigInit=1;
return(0);
}
int init_backing_store (const char * conf_instances_path, unsigned int conf_work_size_mb, unsigned int conf_cache_size_mb)
{
logprintfl (EUCAINFO, "initializing backing store...\n");
if (conf_instances_path == NULL) {
logprintfl (EUCAERROR, "error: INSTANCE_PATH not specified\n");
return ERROR;
}
safe_strncpy (instances_path, conf_instances_path, sizeof (instances_path));
if (check_directory (instances_path)) {
logprintfl (EUCAERROR, "error: INSTANCE_PATH (%s) does not exist!\n", instances_path);
return ERROR;
}
char cache_path [MAX_PATH]; snprintf (cache_path, sizeof (cache_path), "%s/cache", instances_path);
if (ensure_directories_exist (cache_path, 0, NULL, NULL, BACKING_DIRECTORY_PERM) == -1) return ERROR;
char work_path [MAX_PATH]; snprintf (work_path, sizeof (work_path), "%s/work", instances_path);
if (ensure_directories_exist (work_path, 0, NULL, NULL, BACKING_DIRECTORY_PERM) == -1) return ERROR;
unsigned long long cache_limit_blocks = conf_cache_size_mb * 2048; // convert MB to blocks
unsigned long long work_limit_blocks = conf_work_size_mb * 2048;
if (work_limit_blocks==0) { // we take 0 as unlimited
work_limit_blocks = ULLONG_MAX;
}
// by default we let blobstore pick the snapshot policy, which
// will use device mapper if available, which is faster than copying
blobstore_snapshot_t snapshot_policy = BLOBSTORE_SNAPSHOT_ANY;
if (nc_state.disable_snapshots) {
logprintfl (EUCAINFO, "if allocating storage, will avoid using snapshots\n");
snapshot_policy = BLOBSTORE_SNAPSHOT_NONE;
}
blobstore_set_error_function ( &bs_errors );
if (cache_limit_blocks) {
cache_bs = blobstore_open (cache_path, cache_limit_blocks, BLOBSTORE_FLAG_CREAT, BLOBSTORE_FORMAT_DIRECTORY, BLOBSTORE_REVOCATION_LRU, snapshot_policy);
if (cache_bs==NULL) {
logprintfl (EUCAERROR, "ERROR: failed to open/create cache blobstore: %s\n", blobstore_get_error_str(blobstore_get_error()));
return ERROR;
}
}
work_bs = blobstore_open (work_path, work_limit_blocks, BLOBSTORE_FLAG_CREAT, BLOBSTORE_FORMAT_FILES, BLOBSTORE_REVOCATION_NONE, snapshot_policy);
if (work_bs==NULL) {
logprintfl (EUCAERROR, "ERROR: failed to open/create work blobstore: %s\n", blobstore_get_error_str(blobstore_get_error()));
logprintfl (EUCAERROR, "ERROR: %s\n", blobstore_get_last_trace());
blobstore_close (cache_bs);
return ERROR;
}
// set the initial value of the semaphore to the number of
// disk-intensive operations that can run in parallel on this node
if (nc_state.concurrent_disk_ops && (disk_sem = sem_alloc (nc_state.concurrent_disk_ops, "mutex")) == NULL) {
logprintfl (EUCAERROR, "failed to create and initialize disk semaphore\n");
return ERROR;
}
return OK;
}
char* InliningDatabase::compute_file_name(LookupKey* outer, LookupKey* inner, bool create_directories) {
char* name = NEW_RESOURCE_ARRAY(char, 1024);
// Outer key
char* outer_klass_name = mangle_name(klass_string(outer->klass()));
char* outer_selector_name = mangle_name(selector_string(outer->selector()));
if (create_directories) {
if (!check_directory(directory())) return NULL;
}
strcpy(name, directory());
strcat(name, "\\");
strcat(name, outer_klass_name);
if (create_directories) {
if (!check_directory(name)) return NULL;
}
strcat(name, "\\");
strcat(name, outer_selector_name);
if (inner) {
// Inner key
char* inner_klass_name = mangle_name(klass_string(inner->klass()));
char* inner_method_name = mangle_name(method_string(inner->method()));
if (create_directories) {
if (!check_directory(name)) return NULL;
}
strcat(name, "\\");
strcat(name, inner_klass_name);
if (create_directories) {
if (!check_directory(name)) return NULL;
}
strcat(name, "\\");
strcat(name, inner_method_name);
}
strcat(name, ".txt");
return name;
}
/** Check the directory for new file events.
*
* Note:
* If any directory entries are sub-directories and the recursive flag is set,
* then this function recurses on the sub-directories.
*/
void
check_directory(const char *path, struct hooks_t *hooks, struct files_t *files, bool recursive, const time_t timestamp)
{
//struct dirent **entries;
struct dirent *entry;
DIR *dp;
char fullpath[PATH_MAX];
dp=opendir(path);
if(dp == NULL){
fprintf(stderr,"Could not open directory: %s\n", path);
return;
}
while((entry = readdir(dp)) != NULL){
if(streq(entry->d_name, ".") || streq(entry->d_name, "..")){
continue;
}
snprintf(fullpath, PATH_MAX, "%s/%s", path, entry->d_name);
//printf("%s\n", fullpath);
struct stat st;
lstat(fullpath, &st);
if(S_ISDIR(st.st_mode) && recursive){
printf("DIRECTORY: %s\n", entry->d_name);
if(strcmp(entry->d_name,"..") != 0 && strcmp(entry->d_name, ".") != 0){
check_directory(fullpath, hooks, files, recursive, timestamp);
}
}else{
printf("\t%s\n", entry->d_name);
printf("\t\t FILE\n");
if(search_files(files, fullpath) == NULL){
add_file(files, fullpath, st.st_mtime, timestamp);
printf("CREATE EVENT");
//CREATE EVENT
}
else{
printf("We have a file match? WTF");
// compare mtime
// check timestamp
}
//look at hooks and files
//use n as count of files?
}
}
closedir(dp);
}
// This function is used to check the data directory path for safety.
// We check that every sub-directory is owned by the 'system' user
// and exists and is not a symlink. We also check that the full directory
// path is properly owned by the user ID.
static bool check_data_path(const char* data_path, uid_t uid) {
// The path should be absolute.
if (data_path[0] != '/') return false;
// Look for all sub-paths, we do that by finding
// directory separators in the input path and
// checking each sub-path independently.
for (int nn = 1; data_path[nn] != '\0'; nn++) {
char subpath[PATH_MAX];
/* skip non-separator characters */
if (data_path[nn] != '/') continue;
/* handle trailing separator case */
if (data_path[nn+1] == '\0') break;
/* found a separator, check that data_path is not too long. */
if (nn >= (int)(sizeof subpath)) return false;
/* reject any '..' subpath */
if (nn >= 3 &&
data_path[nn-3] == '/' &&
data_path[nn-2] == '.' &&
data_path[nn-1] == '.') {
return false;
}
/* copy to 'subpath', then check ownership */
memcpy(subpath, data_path, nn);
subpath[nn] = '\0';
if (!check_directory(subpath, AID_SYSTEM)) return false;
}
// All sub-paths were checked, now verify that the full data
// directory is owned by the application uid.
return check_directory(data_path, uid);
}
void chk_bogohome(void)
{
if (!check_directory(bogohome)) {
(void)fprintf(stderr, "%s: cannot find bogofilter directory.\n"
"You must specify a directory on the command line, in the config file,\n"
#ifndef __riscos__
"or by using the BOGOFILTER_DIR or HOME environment variables.\n"
#else
"or by ensuring that <Bogofilter$Dir> is set correctly.\n"
#endif
"Program aborting.\n", progname);
exit(EX_ERROR);
}
}
bool
initialize(void)
{
init_default();
check_directory();
if (!load_proxy_config())
return false;
if (file_exist(Config.config_file)) {
return load_config(Config.config_file);
}
return true;
}
void e2fsck_pass3(e2fsck_t ctx)
{
ext2_filsys fs = ctx->fs;
struct dir_info_iter *iter;
#ifdef RESOURCE_TRACK
struct resource_track rtrack;
#endif
struct problem_context pctx;
struct dir_info *dir;
unsigned long maxdirs, count;
init_resource_track(&rtrack, ctx->fs->io);
clear_problem_context(&pctx);
#ifdef MTRACE
mtrace_print("Pass 3");
#endif
if (!(ctx->options & E2F_OPT_PREEN))
fix_problem(ctx, PR_3_PASS_HEADER, &pctx);
/*
* Allocate some bitmaps to do loop detection.
*/
pctx.errcode = e2fsck_allocate_inode_bitmap(fs, _("inode done bitmap"),
EXT2FS_BMAP64_AUTODIR,
"inode_done_map", &inode_done_map);
if (pctx.errcode) {
pctx.num = 2;
fix_problem(ctx, PR_3_ALLOCATE_IBITMAP_ERROR, &pctx);
ctx->flags |= E2F_FLAG_ABORT;
goto abort_exit;
}
print_resource_track(ctx, _("Peak memory"), &ctx->global_rtrack, NULL);
check_root(ctx);
if (ctx->flags & E2F_FLAG_SIGNAL_MASK)
goto abort_exit;
ext2fs_mark_inode_bitmap2(inode_done_map, EXT2_ROOT_INO);
maxdirs = e2fsck_get_num_dirinfo(ctx);
count = 1;
if (ctx->progress)
if ((ctx->progress)(ctx, 3, 0, maxdirs))
goto abort_exit;
iter = e2fsck_dir_info_iter_begin(ctx);
while ((dir = e2fsck_dir_info_iter(ctx, iter)) != 0) {
if (ctx->flags & E2F_FLAG_SIGNAL_MASK)
goto abort_exit;
if (ctx->progress && (ctx->progress)(ctx, 3, count++, maxdirs))
goto abort_exit;
if (ext2fs_test_inode_bitmap2(ctx->inode_dir_map, dir->ino))
if (check_directory(ctx, dir->ino, &pctx))
goto abort_exit;
}
e2fsck_dir_info_iter_end(ctx, iter);
/*
* Force the creation of /lost+found if not present
*/
if ((ctx->flags & E2F_OPT_READONLY) == 0)
e2fsck_get_lost_and_found(ctx, 1);
/*
* If there are any directories that need to be indexed or
* optimized, do it here.
*/
e2fsck_rehash_directories(ctx);
abort_exit:
e2fsck_free_dir_info(ctx);
if (inode_loop_detect) {
ext2fs_free_inode_bitmap(inode_loop_detect);
inode_loop_detect = 0;
}
if (inode_done_map) {
ext2fs_free_inode_bitmap(inode_done_map);
inode_done_map = 0;
}
print_resource_track(ctx, _("Pass 3"), &rtrack, ctx->fs->io);
}
int *parsing_file(char *file_name, int *counter, llist l_args)
{
FILE *fp;
FILE *np;
char *line = NULL;
size_t len = 0;
ssize_t read;
int i = 1;
int comment_count = 0;
DIR *d;
char *directory = make_directory(l_args->directory, file_name);
int sub_dir = l_args->pr_s;
char *org_dir = l_args->directory;
struct dirent *dir;
if (nmatch(file_name, "*/..") == 1 || nmatch(file_name, "*/.") == 1 ||
nmatch(file_name, ".") == 1 || nmatch(file_name, "..") == 1 ||
nmatch(file_name, "no_comment") == 1)
return (counter);
counter[3] = counter[3] + 1;
if (is_directory(file_name) == 1 && nmatch(file_name, org_dir) == 0)
{
d = opendir(file_name);
if (d && sub_dir == 1)
{
printf(ANSI_COLOR_BLUE"!---> Reading directory '%s':\n"ANSI_COLOR_RESET,
file_name);
while ((dir = readdir(d)) != NULL)
{
check_directory(directory, 1);
counter = parsing_file(make_directory(file_name, dir->d_name),
counter, l_args);
}
printf(ANSI_COLOR_BLUE"End of directory '%s' <---!\n"ANSI_COLOR_RESET,
file_name);
return (counter);
closedir(d);
}
return (counter);
}
printf("\n> Reading file: '%s'\n", file_name);
printf("Destination: '%s'\n", directory);
if ((fp = fopen(file_name, "r")) == NULL)
{
printf(ANSI_COLOR_RED"! Error while reading file '%s'\n" ANSI_COLOR_RESET
, (file_name ? file_name : " "));
counter[1] = counter[1] + 1;
return (counter);
}
if ((np = fopen(directory, "w+")) == NULL)
{
printf(ANSI_COLOR_RED"! Error while creating file '%s'\n"ANSI_COLOR_RESET
, (file_name ? file_name : " "));
counter[1] = counter[1] + 1;
return (counter);
}
counter[0] = counter[0] + 1;
while ((read = getline(&line, &len, fp)) != -1)
comment_count = write_file(np, line, comment_count);
printf("Total of comments deleted: %d\n", comment_count);
printf(ANSI_COLOR_GREEN "--> Done for %s\n\n"ANSI_COLOR_RESET, file_name);
counter[2] = counter[2] + comment_count;
return (counter);
fclose(fp);
fclose (np);
}
/**************************
*** MAIN
**************************/
int main(int argc, char **argv)
{
/*
** INIT SIGNALS
*/
set_signals();
/*
** INIT / SETTINGS VARS
*/
client_count = 0;
int port;
/*
** ARGS MANAGEMENT
*/
if(argc != 3 || !is_number(argv[2]))
{
CRITIC("Can't launch with these arguments.", "\tUsage: ./executable <directory> <port>");
}
port = atoi(argv[2]);
if(port > 65535 || port < 1024)
{
CRITIC("Can't launch with this port.", "\tPort must be between 1024 and 65535.");
}
switch(check_directory(argv[1]))
{
case 0:
strncpy(dir_path, argv[1], MAX_PATH - 1);
if(dir_path[strlen(dir_path) - 1] != '/')
strncat(dir_path, "/", 1);
dir_path[MAX_PATH - 1] = '\0';
break;
case 1:
// Ask to create directory
INFO("Directory does not exist, do you want to create it? (yes/no)");
char buffer[MAX_BUF];
fgets(buffer, MAX_BUF, stdin);
// If user said yes
if(strcmp(buffer, "YES\n") == 0 || strcmp(buffer, "yes\n") == 0)
{
// Create directory and set full path
create_directory(argv[1]);
strncpy(dir_path, argv[1], MAX_PATH - 1);
if(dir_path[strlen(dir_path) - 1] != '/')
strncat(dir_path, "/", 1);
dir_path[MAX_PATH - 1] = '\0';
}
else
{
CRITIC("Can't launch with this directory.", "\tDirectory must exists.");
}
break;
case 2:
CRITIC("ERRNO ON STAT", strerror(errno));
break;
case 3:
CRITIC("Can't launch with this directory.", "\tThe given path is not a directory.");
break;
case 4:
CRITIC("Can't launch with this directory.", "\tYou don't have the required permissions.");
default:
CRITIC("Something impossible happened!", "Wrong switch value");
break;
}
// INIT MUTEX
if(pthread_mutex_init(&client_count_mutex, NULL) != 0)
{
CRITIC("Can't create client mutex", "MUTEX INIT ERROR");
}
if(pthread_mutex_init(&client_list_mutex, NULL) != 0)
{
CRITIC("Can't create list mutex", "MUTEX INIT ERROR");
}
/*
** SERVER MANAGEMENT
*/
return start_server(port);
} // int main(int, char**)
/**
* Recursive iteration for file finding
*
* @param __dir - directory to search file in
* @param __rel_dir - relative director name to search file in
* @param __options - finding options
* @param __res_wnd - window with results
* @return zero on success, non-zero otherwise
*/
static int
find_iteration (const wchar_t *__dir, const wchar_t *__rel_dir,
const action_find_options_t *__options,
action_find_res_wnd_t *__res_wnd)
{
int i, j, count;
vfs_dirent_t **eps = NULL;
size_t fn_len;
wchar_t *format, *full_name;
vfs_stat_t stat;
vfs_stat_proc stat_proc;
deque_t *dirs;
wchar_t **dir_data;
__res_wnd->dir_opened = FALSE;
/* Get listing of directory */
/*
* TODO: Add separately displaying of directories and files
*/
count = vfs_scandir (__dir, &eps, 0, vfs_alphasort);
if (count < 0)
{
/* Error getting listing */
return ACTION_ERR;
}
if (TEST_FLAG(__options->flags, AFF_FIND_RECURSIVELY))
{
dirs = deque_create ();
}
/* Get function for stat'ing */
if (TEST_FLAG(__options->flags, AFF_FOLLOW_SYMLINKS))
{
stat_proc = vfs_stat;
}
else
{
stat_proc = vfs_lstat;
}
/* Allocate memory for full file name */
fn_len = wcslen (__dir) + MAX_FILENAME_LEN + 1;
full_name = malloc ((fn_len + 1) * sizeof (wchar_t));
/* Get format mask for correct directory drilling */
if (__dir[wcslen (__dir) - 1] == '/')
{
format = L"%ls%ls";
}
else
{
format = L"%ls/%ls";
}
for (i = 0; i < count; ++i)
{
if (IS_PSEUDODIR (eps[i]->name))
{
vfs_free_dirent (eps[i]);
continue;
}
set_searching_status (__res_wnd, L"Searching in", __rel_dir);
/* Get full file name */
swprintf (full_name, fn_len, format, __dir, eps[i]->name);
/* Stat current node of FS */
if (!stat_proc (full_name, &stat) == VFS_OK)
{
/* Error getting status of file */
vfs_free_dirent (eps[i]);
continue;
}
if (S_ISREG (stat.st_mode))
{
if (check_regular_file (eps[i]->name, full_name,
__options, __res_wnd))
{
append_result (__rel_dir, eps[i]->name, stat, __res_wnd);
++__res_wnd->found_files;
}
}
else if (S_ISDIR (stat.st_mode))
{
/* Of user wants directories to be found... */
if (TEST_FLAG(__options->flags, AFF_FIND_DIRECTORIES))
{
if (check_directory (eps[i]->name, full_name,
__options, __res_wnd))
{
append_result (__rel_dir, eps[i]->name, stat, __res_wnd);
++__res_wnd->found_dirs;
}
}
if (TEST_FLAG(__options->flags, AFF_FIND_RECURSIVELY))
{
dir_data = malloc (2 * sizeof (wchar_t));
dir_data[0] = wcsdup (eps[i]->name);
dir_data[1] = wcsdup (full_name);
deque_push_back (dirs, (void*)dir_data);
}
}
else
{
if (check_special_file (eps[i]->name, full_name,
__options, __res_wnd))
{
append_result (__rel_dir, eps[i]->name, stat, __res_wnd);
++__res_wnd->found_files;
}
}
vfs_free_dirent (eps[i]);
hook_call (L"switch-task-hook", NULL);
if (ACTION_PERFORMED (__res_wnd))
{
/* Free remain dirents */
for (j = i + 1; j < count; ++j)
{
vfs_free_dirent (eps[j]);
}
break;
}
}
SAFE_FREE (eps);
free (full_name);
if (TEST_FLAG(__options->flags, AFF_FIND_RECURSIVELY) &&
!ACTION_PERFORMED (__res_wnd))
{
void *data;
wchar_t *rel_name;
if (__rel_dir[wcslen (__rel_dir) - 1] == '/')
{
format = L"%ls%ls";
}
else
{
format = L"%ls/%ls";
}
fn_len = wcslen (__dir) + MAX_FILENAME_LEN + 1;
rel_name = malloc ((fn_len + 1) * sizeof (wchar_t));
deque_foreach (dirs, data);
/* Drill relative file name */
dir_data = data;
if (!ACTION_PERFORMED (__res_wnd))
{
swprintf (rel_name, fn_len, format, __rel_dir, dir_data[0]);
find_iteration (dir_data[1], rel_name, __options, __res_wnd);
}
free (dir_data);
deque_foreach_done
}
int main(int argc, char *argv[]) {
int sock_control;
boolean has_quit = 0;
struct sockaddr_in address;
if (argc != 3) {
fprintf(stderr, "USAGE: a2client <ip_address> <port_number>\n");
exit(1);
}
//create a tcp socket
if ((sock_control = socket(PF_INET, SOCK_STREAM, IPPROTO_TCP)) < 0) {
perror("\nError in socket()");
exit(1);
}
//construct the struct
memset(&address, 0, sizeof(address)); /* Clear struct */
address.sin_family = AF_INET; /* Internet/IP */
address.sin_addr.s_addr = inet_addr(argv[1]); /* IP address */
address.sin_port = htons(atoi(argv[2])); /* server port */
//connect to the server
if (connect(sock_control, (struct sockaddr *) &address, sizeof(address)) < 0) {
perror("\nError in connect()");
exit(1);
}
//keep getting input from client until they enter QUIT command
//these input from client will be sent as commands to server
while(has_quit == FALSE){
char command[MAX_LENGTH];
char command_temp[MAX_LENGTH];
fgets(command, MAX_LENGTH, stdin); //get input from user
strcat(command, "\r\n");
strcpy(command_temp, command);
boolean has_write = TRUE;
//if doing a PUT command, check if the file in your directory does in fact exist
//if the file does not exists on our (client) directory, do not bother sending
//this PUT command to the server
//(since on a PUT, the server actually makes an empty file in its directory assuming that
//it is going to get data to put in it)
if(strncmp("PUT", command, 3) == 0){
has_write = check_directory(command_temp);
}
if(has_write == TRUE){
//send command to server
if(write(sock_control, command, strlen(command)) < 0){
perror("\nError in write()");
exit(1);
}
char response[MAX_LENGTH];
int n;
//read response from server
if((n = read(sock_control, response, MAX_LENGTH-1))){
response[n] = '\0';
fprintf(stderr, "%s", response);
}
//if user enters GET, LIST or PUT
//will not make a data connection if a response is anything other
//than 103 Command okay
if(strncmp("103", response, 3) == 0){
//if the command is ok, the client will connect to the server to form
//a tcp data connection
create_data_connect(command, argv[1], argv[2]);
}
if(strncmp("QUIT", command, 4) == 0){
has_quit = TRUE;
}
}
}
//when client enters QUIT we quit here
printf("\n\nProcessing complete\n\n");
exit(0);
}
int main()
{
/* Declare automatic variables. */
size_t cmdlen = 0;
char * cmdline = NULL;
int retval;
/* Display the banner. */
print_banner();
/* Display the usage information if the command line is empty. */
cmdlen = _bgetcmd( NULL, 0 );
if( cmdlen == 0 ) {
print_usage();
return( EXIT_FAILURE );
}
/* Include space for the terminating null character. */
cmdlen++;
/* Get the command line. */
cmdline = malloc( cmdlen );
if( cmdline == NULL ) {
return( EXIT_FAILURE );
}
cmdlen = _bgetcmd( cmdline, cmdlen );
/* Initialize the globals. */
initialize_globals();
res_initialize_globals();
/* Initialize the statics, which should be globals in gendev. */
cur_file = (file_info *) malloc( sizeof( file_info ) );
cur_file->filebuf = (char * ) malloc( BUF_SIZE );
cur_file->buflen = BUF_SIZE;
cur_file->scanptr = NULL;
cur_file->usedlen = 0;
cur_token = (token *) malloc( sizeof( token ) );
/* Parse the command line: allocates and sets tgt_path. */
retval = parse_cmdline( cmdline );
if( retval == FAILURE ) {
free( cmdline );
return( EXIT_FAILURE );
}
/* Free the memory held by cmdline and reset it. */
free( cmdline );
cmdline = NULL;
/* Check all files in current directory. */
retval = check_directory();
/* Free the memory held by tgt_path and the statics. */
free( tgt_path );
tgt_path = NULL;
free( cur_file->filebuf );
cur_file->filebuf = NULL;
free( cur_file );
cur_file = NULL;
free( cur_token );
cur_token = NULL;
/* Print the useage if the process failed. */
if( retval == FAILURE ) {
print_usage();
return( EXIT_FAILURE );
}
return( EXIT_SUCCESS );
}
//!
//! Defines the thread that does the actual reboot of an instance.
//!
//! @param[in] arg a transparent pointer to the argument passed to this thread handler
//!
//! @return Always return NULL
//!
static void *rebooting_thread(void *arg)
{
char *xml = NULL;
char resourceName[1][MAX_SENSOR_NAME_LEN] = { "" };
char resourceAlias[1][MAX_SENSOR_NAME_LEN] = { "" };
// ncInstance *instance = ((ncInstance *) arg);
ncInstance *instance = NULL;
struct nc_state_t *nc = NULL;
virDomainPtr dom = NULL;
virConnectPtr conn = NULL;
rebooting_thread_params *params = ((rebooting_thread_params *) arg);
instance = &(params->instance);
nc = &(params->nc);
LOGDEBUG("[%s] spawning rebooting thread\n", instance->instanceId);
if ((conn = lock_hypervisor_conn()) == NULL) {
LOGERROR("[%s] cannot connect to hypervisor to restart instance, giving up\n", instance->instanceId);
EUCA_FREE(params);
return NULL;
}
dom = virDomainLookupByName(conn, instance->instanceId);
if (dom == NULL) {
LOGERROR("[%s] cannot locate instance to reboot, giving up\n", instance->instanceId);
unlock_hypervisor_conn();
EUCA_FREE(params);
return NULL;
}
// obtain the most up-to-date XML for domain from libvirt
xml = virDomainGetXMLDesc(dom, 0);
if (xml == NULL) {
LOGERROR("[%s] cannot obtain metadata for instance to reboot, giving up\n", instance->instanceId);
virDomainFree(dom); // release libvirt resource
unlock_hypervisor_conn();
EUCA_FREE(params);
return NULL;
}
virDomainFree(dom); // release libvirt resource
unlock_hypervisor_conn();
// try shutdown first, then kill it if uncooperative
if (shutdown_then_destroy_domain(instance->instanceId, TRUE) != EUCA_OK) {
LOGERROR("[%s] failed to shutdown and destroy the instance to reboot, giving up\n", instance->instanceId);
EUCA_FREE(params);
return NULL;
}
// Add a shift to values of three of the metrics: ones that
// drop back to zero after a reboot. The shift, which is based
// on the latest value, ensures that values sent upstream do
// not go backwards .
sensor_shift_metric(instance->instanceId, "CPUUtilization");
sensor_shift_metric(instance->instanceId, "NetworkIn");
sensor_shift_metric(instance->instanceId, "NetworkOut");
if ((conn = lock_hypervisor_conn()) == NULL) {
LOGERROR("[%s] cannot connect to hypervisor to restart instance, giving up\n", instance->instanceId);
EUCA_FREE(params);
return NULL;
}
// domain is now shut down, create a new one with the same XML
LOGINFO("[%s] rebooting\n", instance->instanceId);
if (!strcmp(nc->pEucaNet->sMode, NETMODE_VPCMIDO)) {
// need to sleep to allow midolman to update the VM interface
sleep(10);
}
dom = virDomainCreateLinux(conn, xml, 0);
if (dom == NULL) {
LOGERROR("[%s] failed to restart instance\n", instance->instanceId);
change_state(instance, SHUTOFF);
} else {
euca_strncpy(resourceName[0], instance->instanceId, MAX_SENSOR_NAME_LEN);
sensor_refresh_resources(resourceName, resourceAlias, 1); // refresh stats so we set base value accurately
virDomainFree(dom);
if (!strcmp(nc->pEucaNet->sMode, NETMODE_VPCMIDO)) {
char iface[16], cmd[EUCA_MAX_PATH], obuf[256], ebuf[256], sPath[EUCA_MAX_PATH];
int rc;
snprintf(iface, 16, "vn_%s", instance->instanceId);
// If this device does not have a 'brport' path, this isn't a bridge device
snprintf(sPath, EUCA_MAX_PATH, "/sys/class/net/%s/brport/", iface);
if (!check_directory(sPath)) {
LOGDEBUG("[%s] removing instance interface %s from host bridge\n", instance->instanceId, iface);
snprintf(cmd, EUCA_MAX_PATH, "%s brctl delif %s %s", nc->rootwrap_cmd_path, instance->params.guestNicDeviceName, iface);
rc = timeshell(cmd, obuf, ebuf, 256, 10);
if (rc) {
LOGERROR("unable to remove instance interface from bridge after launch: instance will not be able to connect to midonet (will not connect to network): check bridge/libvirt/kvm health\n");
}
}
// Repeat process for secondary interfaces as well
for (int i=0; i < EUCA_MAX_NICS; i++) {
if (strlen(instance->secNetCfgs[i].interfaceId) == 0)
continue;
snprintf(iface, 16, "vn_%s", instance->secNetCfgs[i].interfaceId);
// If this device does not have a 'brport' path, this isn't a bridge device
snprintf(sPath, EUCA_MAX_PATH, "/sys/class/net/%s/brport/", iface);
if (!check_directory(sPath)) {
LOGDEBUG("[%s] removing instance interface %s from host bridge\n", instance->instanceId, iface);
snprintf(cmd, EUCA_MAX_PATH, "%s brctl delif %s %s", nc->rootwrap_cmd_path, instance->params.guestNicDeviceName, iface);
rc = timeshell(cmd, obuf, ebuf, 256, 10);
if (rc) {
LOGERROR("unable to remove instance interface from bridge after launch: instance will not be able to connect to midonet (will not connect to network): check bridge/libvirt/kvm health\n");
}
}
}
}
}
EUCA_FREE(xml);
unlock_hypervisor_conn();
unset_corrid(get_corrid());
EUCA_FREE(params);
return NULL;
}
static krb5_error_code KRB5_LIB_CALL
kuserok_user_k5login_plug_f(void *plug_ctx, krb5_context context,
const char *rule, unsigned int flags,
const char *k5login_dir, const char *luser,
krb5_const_principal principal,
krb5_boolean *result)
{
#ifdef _WIN32
return KRB5_PLUGIN_NO_HANDLE;
#else
char *path;
char *path_exp;
const char *profile_dir = NULL;
krb5_error_code ret;
krb5_boolean found_file = FALSE;
struct passwd pw, *pwd = NULL;
char pwbuf[2048];
if (strcmp(rule, "USER-K5LOGIN") != 0)
return KRB5_PLUGIN_NO_HANDLE;
profile_dir = k5login_dir;
if (profile_dir == NULL) {
/* Don't deadlock with gssd or anything of the sort */
if (!_krb5_homedir_access(context))
return KRB5_PLUGIN_NO_HANDLE;
if (getpwnam_r(luser, &pw, pwbuf, sizeof(pwbuf), &pwd) != 0) {
krb5_set_error_message(context, errno, "User unknown (getpwnam_r())");
return KRB5_PLUGIN_NO_HANDLE;
}
if (pwd == NULL) {
krb5_set_error_message(context, errno, "User unknown (getpwnam())");
return KRB5_PLUGIN_NO_HANDLE;
}
profile_dir = pwd->pw_dir;
}
#define KLOGIN "/.k5login"
if (asprintf(&path, "%s/.k5login.d", profile_dir) == -1)
return krb5_enomem(context);
ret = _krb5_expand_path_tokensv(context, path, 1, &path_exp,
"luser", luser, NULL);
free(path);
if (ret)
return ret;
path = path_exp;
/* check user's ~/.k5login */
path[strlen(path) - strlen(".d")] = '\0';
ret = check_one_file(context, path, luser, FALSE, principal, result);
/*
* A match in ~/.k5login is sufficient. A non-match, falls through to the
* .k5login.d code below.
*/
if (ret == 0 && *result == TRUE) {
free(path);
return 0;
}
if (ret != ENOENT)
found_file = TRUE;
/*
* A match in ~/.k5login.d/somefile is sufficient. A non-match, falls
* through to the code below that handles negative results.
*
* XXX: put back the .d; clever|hackish? you decide
*/
path[strlen(path)] = '.';
ret = check_directory(context, path, luser, FALSE, principal, result);
free(path);
if (ret == 0 && *result == TRUE)
return 0;
if (ret != ENOENT && ret != ENOTDIR)
found_file = TRUE;
/*
* When either ~/.k5login or ~/.k5login.d/ exists, but neither matches
* and we're authoritative, we're done. Otherwise, give other plugins
* a chance.
*/
*result = FALSE;
if (found_file && (flags & KUSEROK_K5LOGIN_IS_AUTHORITATIVE))
return 0;
return KRB5_PLUGIN_NO_HANDLE;
#endif
}
int
main(int argc, const char **argv)
{
int res = 0;
int optCount = 0;
dbgIn = stdin;
conOut = stdout;
(void)conIn;
(void)dbgOut;
memset(&cache, 0, sizeof(LIST));
memset(&sources, 0, sizeof(LIST));
stat_clear(&summ);
memset(&revinfo, 0, sizeof(REVINFO));
clearLastLine();
optionInit(argc, argv);
optCount = optionParse(argc, argv);
if (optCount < 0)
{
return optCount;
}
argc -= optCount;
if (opt_Revision && (strcmp(opt_Revision, "update") == 0))
{
res = updateSvnlog();
return res;
}
if (check_directory(opt_force))
return 3;
create_cache(opt_force, 0);
if (opt_exit)
return 0;
read_cache();
l2l_dbg(4, "Cache read complete\n");
if (set_LogFile(&logFile))
return 2;
l2l_dbg(4, "opt_logFile processed\n");
if (opt_Pipe)
{
l2l_dbg(3, "Command line: \"%s\"\n",opt_Pipe);
if (!(dbgIn = POPEN(opt_Pipe, "r")))
{
dbgIn = stdin; //restore
l2l_dbg(0, "Could not popen '%s' (%s)\n", opt_Pipe, strerror(errno));
free(opt_Pipe); opt_Pipe = NULL;
}
}
l2l_dbg(4, "opt_Pipe processed\n");
if (argc > 1)
{ // translate {<exefile> <offset>}
int i = 1;
const char *exefile = NULL;
const char *offset = NULL;
char Line[LINESIZE + 1];
while (i < argc)
{
Line[0] = '\0';
offset = argv[optCount + i++];
if (isOffset(offset))
{
if (exefile)
{
l2l_dbg(2, "translating %s %s\n", exefile, offset);
translate_file(exefile, my_atoi(offset), Line);
printf("%s\n", Line);
report(conOut);
}
else
{
l2l_dbg(0, "<exefile> expected\n");
res = 3;
break;
}
}
else
{
// Not an offset so must be an exefile:
exefile = offset;
}
}
}
else
{ // translate logging from stdin
translate_files(dbgIn, conOut);
}
if (logFile)
fclose(logFile);
if (opt_Pipe)
PCLOSE(dbgIn);
return res;
}
static int
inode_callback(sam_perm_inode_t *ip, void *arg) {
inode_cb_arg_t *cb_arg = (inode_cb_arg_t *)arg;
boolean_t retry_inode;
/* Inodes that shouldn't be checked */
if (!IS_DB_INODE(ip->di.id.ino) ||
!IS_DB_INODE(ip->di.parent_id.ino)) {
return (0);
}
retry:
retry_inode = FALSE;
if (ip->di.id.ino == cur_check.inode.ino) {
if (ip->di.mode == 0 || S_ISEXT(ip->di.mode)) {
QUIET_PRINT(stderr, "Inactive inode %d "
"found in database.\n",
ip->di.id.ino);
add_repair_entry(ip->di.id,
ip->di.parent_id, TRUE);
} else {
/*
* Check the inode and directory. Repair reason
* is printed in the corresponding check method.
*/
if (check_inode(ip) < 0) {
add_repair_entry(ip->di.id,
ip->di.parent_id, FALSE);
} else if (!fast_scan && S_ISDIR(ip->di.mode)) {
if (check_directory(cb_arg->dir_con,
cb_arg->dir_stmt, ip) < 0) {
add_repair_entry(ip->di.id,
ip->di.parent_id, TRUE);
}
}
}
} else if (ip->di.id.ino < cur_check.inode.ino) {
/* In-use inodes should be in database */
if (!(ip->di.mode == 0 || S_ISEXT(ip->di.mode))) {
QUIET_PRINT(stderr, "Inode %d does "
"not exist in database.\n",
ip->di.id.ino);
add_repair_entry(ip->di.id,
ip->di.parent_id, TRUE);
}
return (0);
} else { /* ip->di.id.ino > cur_check.inode.ino */
/* Database is incorrect, parent unknown */
QUIET_PRINT(stderr, "Erroneous inode %d "
"found in database.\n",
cur_check.inode.ino);
sam_id_t id = {cur_check.inode.ino,
cur_check.inode.gen};
sam_id_t pid = {0, 0};
add_repair_entry(id, pid, TRUE);
retry_inode = TRUE;
}
/* Get next inode to check from database. */
if (next_check_ino(cb_arg->check_stmt) < 0) {
fprintf(stderr, "Error getting check value.\n");
return (-1);
}
if (retry_inode) {
goto retry;
}
return (0);
}
//!
//! Initialize the backing store. Called during initialization of node controller.
//!
//! @param[in] conf_instances_path path to where the instances information are stored
//! @param[in] conf_work_size_mb the work blobstore size limit in MB (if 0 then unlimitted)
//! @param[in] conf_cache_size_mb the cache blobstore size limit in MB (if 0 then cache isn't used)
//!
//! @return EUCA_OK on success or the following error codes:
//! \li EUCA_INVALID_ERROR: if any parameter does not meet the preconditions
//! \li EUCA_ACCESS_ERROR: if we fail to access our cache and work directories
//! \li EUCA_PERMISSION_ERROR: if we fail to create the cache or work stores.
//!
//! @pre The conf_instances_path field must not be NULL
//!
//! @post On success, the backing store module is initialized and the following happened:
//! \li our global instance_path variable is set with the given conf_instance_path
//! \li the work blobstore is created and our global work_bs variable is set
//! \li the cache blobstore is created if necessary and the cache_bs variable is set
//! \li the disk semaphore is created if necessary
//!
int init_backing_store(const char *conf_instances_path, unsigned int conf_work_size_mb, unsigned int conf_cache_size_mb)
{
char cache_path[EUCA_MAX_PATH] = "";
char work_path[EUCA_MAX_PATH] = "";
unsigned long long cache_limit_blocks = 0;
unsigned long long work_limit_blocks = 0;
blobstore_snapshot_t snapshot_policy = BLOBSTORE_SNAPSHOT_ANY;
LOGINFO("initializing backing store...\n");
// Make sure we have a valid intance path passed to us
if (conf_instances_path == NULL) {
LOGERROR("INSTANCE_PATH not specified\n");
return (EUCA_INVALID_ERROR);
}
// Set our global instance_path variable with the content of conf_instance_path
euca_strncpy(instances_path, conf_instances_path, sizeof(instances_path));
if (check_directory(instances_path)) {
LOGERROR("INSTANCE_PATH (%s) does not exist!\n", instances_path);
return (EUCA_ACCESS_ERROR);
}
// Check if our cache path exist. If not it should get crated
snprintf(cache_path, sizeof(cache_path), "%s/cache", instances_path);
if (ensure_directories_exist(cache_path, 0, NULL, NULL, BACKING_DIRECTORY_PERM) == -1)
return (EUCA_ACCESS_ERROR);
// Check if our work path exist. If not it should get crated
snprintf(work_path, sizeof(work_path), "%s/work", instances_path);
if (ensure_directories_exist(work_path, 0, NULL, NULL, BACKING_DIRECTORY_PERM) == -1)
return (EUCA_ACCESS_ERROR);
// convert MB to blocks
cache_limit_blocks = (unsigned long long)conf_cache_size_mb *2048;
work_limit_blocks = (unsigned long long)conf_work_size_mb *2048;
// we take 0 as unlimited
if (work_limit_blocks == 0) {
work_limit_blocks = ULLONG_MAX;
}
// by default we let blobstore pick the snapshot policy, which
// will use device mapper if available, which is faster than copying
snapshot_policy = BLOBSTORE_SNAPSHOT_ANY;
if (nc_state.disable_snapshots) {
LOGINFO("if allocating storage, will avoid using snapshots\n");
snapshot_policy = BLOBSTORE_SNAPSHOT_NONE;
}
// Set the backing store error callback function
blobstore_set_error_function(&bs_errors);
// Do we need to create a cache blobstore
if (cache_limit_blocks) {
cache_bs = blobstore_open(cache_path, cache_limit_blocks, BLOBSTORE_FLAG_CREAT, BLOBSTORE_FORMAT_DIRECTORY, BLOBSTORE_REVOCATION_LRU, snapshot_policy);
if (cache_bs == NULL) {
LOGERROR("failed to open/create cache blobstore: %s\n", blobstore_get_error_str(blobstore_get_error()));
return (EUCA_PERMISSION_ERROR);
}
}
// Lets open the work blobstore
work_bs = blobstore_open(work_path, work_limit_blocks, BLOBSTORE_FLAG_CREAT, BLOBSTORE_FORMAT_FILES, BLOBSTORE_REVOCATION_NONE, snapshot_policy);
if (work_bs == NULL) {
LOGERROR("failed to open/create work blobstore: %s\n", blobstore_get_error_str(blobstore_get_error()));
LOGERROR("%s\n", blobstore_get_last_trace());
BLOBSTORE_CLOSE(cache_bs);
return (EUCA_PERMISSION_ERROR);
}
// set the initial value of the semaphore to the number of
// disk-intensive operations that can run in parallel on this node
if (nc_state.concurrent_disk_ops && ((disk_sem = sem_alloc(nc_state.concurrent_disk_ops, IPC_MUTEX_SEMAPHORE)) == NULL)) {
LOGERROR("failed to create and initialize disk semaphore\n");
return (EUCA_PERMISSION_ERROR);
}
return (EUCA_OK);
}
static UINT search_directory( MSIPACKAGE *package, MSISIGNATURE *sig, const WCHAR *path, int depth, WCHAR **appValue )
{
UINT rc;
DWORD attr;
LPWSTR val = NULL;
TRACE("%p, %p, %s, %d, %p\n", package, sig, debugstr_w(path), depth, appValue);
if (is_full_path( path ))
{
if (sig->File)
rc = recurse_search_directory( package, &val, sig, path, depth );
else
{
/* Recursively searching a directory makes no sense when the
* directory to search is the thing you're trying to find.
*/
rc = check_directory( package, path, &val );
}
}
else
{
WCHAR pathWithDrive[MAX_PATH] = { 'C',':','\\',0 };
DWORD drives = GetLogicalDrives();
int i;
rc = ERROR_SUCCESS;
for (i = 0; rc == ERROR_SUCCESS && !val && i < 26; i++)
{
if (!(drives & (1 << i)))
continue;
pathWithDrive[0] = 'A' + i;
if (GetDriveTypeW(pathWithDrive) != DRIVE_FIXED)
continue;
lstrcpynW(pathWithDrive + 3, path, ARRAY_SIZE(pathWithDrive) - 3);
if (sig->File)
rc = recurse_search_directory( package, &val, sig, pathWithDrive, depth );
else
rc = check_directory( package, pathWithDrive, &val );
}
}
attr = msi_get_file_attributes( package, val );
if (attr != INVALID_FILE_ATTRIBUTES && (attr & FILE_ATTRIBUTE_DIRECTORY) &&
val && val[lstrlenW(val) - 1] != '\\')
{
val = msi_realloc(val, (lstrlenW(val) + 2) * sizeof(WCHAR));
if (!val)
rc = ERROR_OUTOFMEMORY;
else
PathAddBackslashW(val);
}
*appValue = val;
TRACE("returning %d\n", rc);
return rc;
}