/* $Id$ */
/*
* This file is part of OpenTTD.
* OpenTTD is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, version 2.
* OpenTTD is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
* See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with OpenTTD. If not, see .
*/
/** @file fileio.cpp Standard In/Out file operations */
#include "stdafx.h"
#include "fileio_func.h"
#include "debug.h"
#include "fios.h"
#include "string_func.h"
#include "tar_type.h"
#ifdef WIN32
#include
# define access _taccess
#elif defined(__HAIKU__)
#include
#include
#else
#include
#include
#endif
#include
#include
/** Size of the #Fio data buffer. */
#define FIO_BUFFER_SIZE 512
/** Structure for keeping several open files with just one data buffer. */
struct Fio {
byte *buffer, *buffer_end; ///< position pointer in local buffer and last valid byte of buffer
size_t pos; ///< current (system) position in file
FILE *cur_fh; ///< current file handle
const char *filename; ///< current filename
FILE *handles[MAX_FILE_SLOTS]; ///< array of file handles we can have open
byte buffer_start[FIO_BUFFER_SIZE]; ///< local buffer when read from file
const char *filenames[MAX_FILE_SLOTS]; ///< array of filenames we (should) have open
char *shortnames[MAX_FILE_SLOTS]; ///< array of short names for spriteloader's use
#if defined(LIMITED_FDS)
uint open_handles; ///< current amount of open handles
uint usage_count[MAX_FILE_SLOTS]; ///< count how many times this file has been opened
#endif /* LIMITED_FDS */
};
static Fio _fio; ///< #Fio instance.
/** Whether the working directory should be scanned. */
static bool _do_scan_working_directory = true;
extern char *_config_file;
extern char *_highscore_file;
/**
* Get position in the current file.
* @return Position in the file.
*/
size_t FioGetPos()
{
return _fio.pos + (_fio.buffer - _fio.buffer_end);
}
/**
* Get the filename associated with a slot.
* @param slot Index of queried file.
* @return Name of the file.
*/
const char *FioGetFilename(uint8 slot)
{
return _fio.shortnames[slot];
}
/**
* Seek in the current file.
* @param pos New position.
* @param mode Type of seek (\c SEEK_CUR means \a pos is relative to current position, \c SEEK_SET means \a pos is absolute).
*/
void FioSeekTo(size_t pos, int mode)
{
if (mode == SEEK_CUR) pos += FioGetPos();
_fio.buffer = _fio.buffer_end = _fio.buffer_start + FIO_BUFFER_SIZE;
_fio.pos = pos;
fseek(_fio.cur_fh, _fio.pos, SEEK_SET);
}
#if defined(LIMITED_FDS)
static void FioRestoreFile(int slot)
{
/* Do we still have the file open, or should we reopen it? */
if (_fio.handles[slot] == NULL) {
DEBUG(misc, 6, "Restoring file '%s' in slot '%d' from disk", _fio.filenames[slot], slot);
FioOpenFile(slot, _fio.filenames[slot]);
}
_fio.usage_count[slot]++;
}
#endif /* LIMITED_FDS */
/**
* Switch to a different file and seek to a position.
* @param slot Slot number of the new file.
* @param pos New absolute position in the new file.
*/
void FioSeekToFile(uint8 slot, size_t pos)
{
FILE *f;
#if defined(LIMITED_FDS)
/* Make sure we have this file open */
FioRestoreFile(slot);
#endif /* LIMITED_FDS */
f = _fio.handles[slot];
assert(f != NULL);
_fio.cur_fh = f;
_fio.filename = _fio.filenames[slot];
FioSeekTo(pos, SEEK_SET);
}
/**
* Read a byte from the file.
* @return Read byte.
*/
byte FioReadByte()
{
if (_fio.buffer == _fio.buffer_end) {
_fio.buffer = _fio.buffer_start;
size_t size = fread(_fio.buffer, 1, FIO_BUFFER_SIZE, _fio.cur_fh);
_fio.pos += size;
_fio.buffer_end = _fio.buffer_start + size;
if (size == 0) return 0;
}
return *_fio.buffer++;
}
/**
* Skip \a n bytes ahead in the file.
* @param n Number of bytes to skip reading.
*/
void FioSkipBytes(int n)
{
for (;;) {
int m = min(_fio.buffer_end - _fio.buffer, n);
_fio.buffer += m;
n -= m;
if (n == 0) break;
FioReadByte();
n--;
}
}
/**
* Read a word (16 bits) from the file (in low endian format).
* @return Read word.
*/
uint16 FioReadWord()
{
byte b = FioReadByte();
return (FioReadByte() << 8) | b;
}
/**
* Read a double word (32 bits) from the file (in low endian format).
* @return Read word.
*/
uint32 FioReadDword()
{
uint b = FioReadWord();
return (FioReadWord() << 16) | b;
}
/**
* Read a block.
* @param ptr Destination buffer.
* @param size Number of bytes to read.
*/
void FioReadBlock(void *ptr, size_t size)
{
FioSeekTo(FioGetPos(), SEEK_SET);
_fio.pos += fread(ptr, 1, size, _fio.cur_fh);
}
/**
* Close the file at the given slot number.
* @param slot File index to close.
*/
static inline void FioCloseFile(int slot)
{
if (_fio.handles[slot] != NULL) {
fclose(_fio.handles[slot]);
free(_fio.shortnames[slot]);
_fio.shortnames[slot] = NULL;
_fio.handles[slot] = NULL;
#if defined(LIMITED_FDS)
_fio.open_handles--;
#endif /* LIMITED_FDS */
}
}
/** Close all slotted open files. */
void FioCloseAll()
{
for (int i = 0; i != lengthof(_fio.handles); i++) {
FioCloseFile(i);
}
}
#if defined(LIMITED_FDS)
static void FioFreeHandle()
{
/* If we are about to open a file that will exceed the limit, close a file */
if (_fio.open_handles + 1 == LIMITED_FDS) {
uint i, count;
int slot;
count = UINT_MAX;
slot = -1;
/* Find the file that is used the least */
for (i = 0; i < lengthof(_fio.handles); i++) {
if (_fio.handles[i] != NULL && _fio.usage_count[i] < count) {
count = _fio.usage_count[i];
slot = i;
}
}
assert(slot != -1);
DEBUG(misc, 6, "Closing filehandler '%s' in slot '%d' because of fd-limit", _fio.filenames[slot], slot);
FioCloseFile(slot);
}
}
#endif /* LIMITED_FDS */
/**
* Open a slotted file.
* @param slot Index to assign.
* @param filename Name of the file at the disk.
*/
void FioOpenFile(int slot, const char *filename)
{
FILE *f;
#if defined(LIMITED_FDS)
FioFreeHandle();
#endif /* LIMITED_FDS */
f = FioFOpenFile(filename);
if (f == NULL) usererror("Cannot open file '%s'", filename);
uint32 pos = ftell(f);
FioCloseFile(slot); // if file was opened before, close it
_fio.handles[slot] = f;
_fio.filenames[slot] = filename;
/* Store the filename without path and extension */
const char *t = strrchr(filename, PATHSEPCHAR);
_fio.shortnames[slot] = strdup(t == NULL ? filename : t);
char *t2 = strrchr(_fio.shortnames[slot], '.');
if (t2 != NULL) *t2 = '\0';
strtolower(_fio.shortnames[slot]);
#if defined(LIMITED_FDS)
_fio.usage_count[slot] = 0;
_fio.open_handles++;
#endif /* LIMITED_FDS */
FioSeekToFile(slot, pos);
}
static const char * const _subdirs[NUM_SUBDIRS] = {
"",
"save" PATHSEP,
"save" PATHSEP "autosave" PATHSEP,
"scenario" PATHSEP,
"scenario" PATHSEP "heightmap" PATHSEP,
"gm" PATHSEP,
"data" PATHSEP,
"lang" PATHSEP,
"ai" PATHSEP,
"ai" PATHSEP "library" PATHSEP,
};
const char *_searchpaths[NUM_SEARCHPATHS];
TarList _tar_list;
TarFileList _tar_filelist;
typedef std::map TarLinkList;
static TarLinkList _tar_linklist; ///< List of directory links
/**
* Check whether the given file exists
* @param filename the file to try for existence.
* @param subdir the subdirectory to look in
* @return true if and only if the file can be opened
*/
bool FioCheckFileExists(const char *filename, Subdirectory subdir)
{
FILE *f = FioFOpenFile(filename, "rb", subdir);
if (f == NULL) return false;
FioFCloseFile(f);
return true;
}
/**
* Test whether the given filename exists.
* @param filename the file to test.
* @return true if and only if the file exists.
*/
bool FileExists(const char *filename)
{
#if defined(WINCE)
/* There is always one platform that doesn't support basic commands... */
HANDLE hand = CreateFile(OTTD2FS(filename), 0, 0, NULL, OPEN_EXISTING, 0, NULL);
if (hand == INVALID_HANDLE_VALUE) return 1;
CloseHandle(hand);
return 0;
#else
return access(OTTD2FS(filename), 0) == 0;
#endif
}
/**
* Close a file in a safe way.
*/
void FioFCloseFile(FILE *f)
{
fclose(f);
}
char *FioGetFullPath(char *buf, size_t buflen, Searchpath sp, Subdirectory subdir, const char *filename)
{
assert(subdir < NUM_SUBDIRS);
assert(sp < NUM_SEARCHPATHS);
snprintf(buf, buflen, "%s%s%s", _searchpaths[sp], _subdirs[subdir], filename);
return buf;
}
/**
* Find a path to the filename in one of the search directories.
* @param buf [out] Destination buffer for the path.
* @param buflen Length of the destination buffer.
* @param subdir Subdirectory to try.
* @param filename Filename to look for.
* @return \a buf containing the path if the path was found, else \c NULL.
*/
char *FioFindFullPath(char *buf, size_t buflen, Subdirectory subdir, const char *filename)
{
Searchpath sp;
assert(subdir < NUM_SUBDIRS);
FOR_ALL_SEARCHPATHS(sp) {
FioGetFullPath(buf, buflen, sp, subdir, filename);
if (FileExists(buf)) return buf;
#if !defined(WIN32)
/* Be, as opening files, aware that sometimes the filename
* might be in uppercase when it is in lowercase on the
* disk. Of course Windows doesn't care about casing. */
if (strtolower(buf + strlen(_searchpaths[sp]) - 1) && FileExists(buf)) return buf;
#endif
}
return NULL;
}
char *FioAppendDirectory(char *buf, size_t buflen, Searchpath sp, Subdirectory subdir)
{
assert(subdir < NUM_SUBDIRS);
assert(sp < NUM_SEARCHPATHS);
snprintf(buf, buflen, "%s%s", _searchpaths[sp], _subdirs[subdir]);
return buf;
}
char *FioGetDirectory(char *buf, size_t buflen, Subdirectory subdir)
{
Searchpath sp;
/* Find and return the first valid directory */
FOR_ALL_SEARCHPATHS(sp) {
char *ret = FioAppendDirectory(buf, buflen, sp, subdir);
if (FileExists(buf)) return ret;
}
/* Could not find the directory, fall back to a base path */
ttd_strlcpy(buf, _personal_dir, buflen);
return buf;
}
static FILE *FioFOpenFileSp(const char *filename, const char *mode, Searchpath sp, Subdirectory subdir, size_t *filesize)
{
#if defined(WIN32) && defined(UNICODE)
/* fopen is implemented as a define with ellipses for
* Unicode support (prepend an L). As we are not sending
* a string, but a variable, it 'renames' the variable,
* so make that variable to makes it compile happily */
wchar_t Lmode[5];
MultiByteToWideChar(CP_ACP, 0, mode, -1, Lmode, lengthof(Lmode));
#endif
FILE *f = NULL;
char buf[MAX_PATH];
if (subdir == NO_DIRECTORY) {
strecpy(buf, filename, lastof(buf));
} else {
snprintf(buf, lengthof(buf), "%s%s%s", _searchpaths[sp], _subdirs[subdir], filename);
}
#if defined(WIN32)
if (mode[0] == 'r' && GetFileAttributes(OTTD2FS(buf)) == INVALID_FILE_ATTRIBUTES) return NULL;
#endif
f = fopen(buf, mode);
#if !defined(WIN32)
if (f == NULL && strtolower(buf + ((subdir == NO_DIRECTORY) ? 0 : strlen(_searchpaths[sp]) - 1))) {
f = fopen(buf, mode);
}
#endif
if (f != NULL && filesize != NULL) {
/* Find the size of the file */
fseek(f, 0, SEEK_END);
*filesize = ftell(f);
fseek(f, 0, SEEK_SET);
}
return f;
}
/**
* Opens a file from inside a tar archive.
* @param entry The entry to open.
* @param filesize [out] If not \c NULL, size of the opened file.
* @return File handle of the opened file, or \c NULL if the file is not available.
* @note The file is read from within the tar file, and may not return \c EOF after reading the whole file.
*/
FILE *FioFOpenFileTar(TarFileListEntry *entry, size_t *filesize)
{
FILE *f = fopen(entry->tar_filename, "rb");
if (f == NULL) return f;
fseek(f, entry->position, SEEK_SET);
if (filesize != NULL) *filesize = entry->size;
return f;
}
/**
* Opens a OpenTTD file somewhere in a personal or global directory.
* @param filename Name of the file to open.
* @param subdir Subdirectory to open.
* @param filename Name of the file to open.
* @return File handle of the opened file, or \c NULL if the file is not available.
*/
FILE *FioFOpenFile(const char *filename, const char *mode, Subdirectory subdir, size_t *filesize)
{
FILE *f = NULL;
Searchpath sp;
assert(subdir < NUM_SUBDIRS || subdir == NO_DIRECTORY);
FOR_ALL_SEARCHPATHS(sp) {
f = FioFOpenFileSp(filename, mode, sp, subdir, filesize);
if (f != NULL || subdir == NO_DIRECTORY) break;
}
/* We can only use .tar in case of data-dir, and read-mode */
if (f == NULL && mode[0] == 'r') {
static const uint MAX_RESOLVED_LENGTH = 2 * (100 + 100 + 155) + 1; // Enough space to hold two filenames plus link. See 'TarHeader'.
char resolved_name[MAX_RESOLVED_LENGTH];
/* Filenames in tars are always forced to be lowercase */
strecpy(resolved_name, filename, lastof(resolved_name));
strtolower(resolved_name);
size_t resolved_len = strlen(resolved_name);
/* Resolve ONE directory link */
for (TarLinkList::iterator link = _tar_linklist.begin(); link != _tar_linklist.end(); link++) {
const std::string &src = link->first;
size_t len = src.length();
if (resolved_len >= len && resolved_name[len - 1] == PATHSEPCHAR && strncmp(src.c_str(), resolved_name, len) == 0) {
/* Apply link */
char resolved_name2[MAX_RESOLVED_LENGTH];
const std::string &dest = link->second;
strecpy(resolved_name2, &(resolved_name[len]), lastof(resolved_name2));
strecpy(resolved_name, dest.c_str(), lastof(resolved_name));
strecpy(&(resolved_name[dest.length()]), resolved_name2, lastof(resolved_name));
break; // Only resolve one level
}
}
TarFileList::iterator it = _tar_filelist.find(resolved_name);
if (it != _tar_filelist.end()) {
f = FioFOpenFileTar(&((*it).second), filesize);
}
}
/* Sometimes a full path is given. To support
* the 'subdirectory' must be 'removed'. */
if (f == NULL && subdir != NO_DIRECTORY) {
f = FioFOpenFile(filename, mode, NO_DIRECTORY, filesize);
}
return f;
}
/**
* Create a directory with the given name
* @param name the new name of the directory
*/
static void FioCreateDirectory(const char *name)
{
#if defined(WIN32) || defined(WINCE)
CreateDirectory(OTTD2FS(name), NULL);
#elif defined(OS2) && !defined(__INNOTEK_LIBC__)
mkdir(OTTD2FS(name));
#elif defined(__MORPHOS__) || defined(__AMIGAOS__)
char buf[MAX_PATH];
ttd_strlcpy(buf, name, MAX_PATH);
size_t len = strlen(name) - 1;
if (buf[len] == '/') {
buf[len] = '\0'; // Kill pathsep, so mkdir() will not fail
}
mkdir(OTTD2FS(buf), 0755);
#else
mkdir(OTTD2FS(name), 0755);
#endif
}
/**
* Appends, if necessary, the path separator character to the end of the string.
* It does not add the path separator to zero-sized strings.
* @param buf string to append the separator to
* @param buflen the length of \a buf.
* @return true iff the operation succeeded
*/
bool AppendPathSeparator(char *buf, size_t buflen)
{
size_t s = strlen(buf);
/* Length of string + path separator + '\0' */
if (s != 0 && buf[s - 1] != PATHSEPCHAR) {
if (s + 2 >= buflen) return false;
buf[s] = PATHSEPCHAR;
buf[s + 1] = '\0';
}
return true;
}
/**
* Allocates and files a variable with the full path
* based on the given directory.
* @param dir the directory to base the path on
* @return the malloced full path
*/
char *BuildWithFullPath(const char *dir)
{
char *dest = MallocT(MAX_PATH);
ttd_strlcpy(dest, dir, MAX_PATH);
/* Check if absolute or relative path */
const char *s = strchr(dest, PATHSEPCHAR);
/* Add absolute path */
if (s == NULL || dest != s) {
if (getcwd(dest, MAX_PATH) == NULL) *dest = '\0';
AppendPathSeparator(dest, MAX_PATH);
ttd_strlcat(dest, dir, MAX_PATH);
}
AppendPathSeparator(dest, MAX_PATH);
return dest;
}
/**
* Find the first directory in a tar archive.
* @param tarname the name of the tar archive to look in.
*/
const char *FioTarFirstDir(const char *tarname)
{
TarList::iterator it = _tar_list.find(tarname);
if (it == _tar_list.end()) return NULL;
return (*it).second.dirname;
}
static void TarAddLink(const std::string &srcParam, const std::string &destParam)
{
std::string src = srcParam;
std::string dest = destParam;
/* Tar internals assume lowercase */
std::transform(src.begin(), src.end(), src.begin(), tolower);
std::transform(dest.begin(), dest.end(), dest.begin(), tolower);
TarFileList::iterator dest_file = _tar_filelist.find(dest);
if (dest_file != _tar_filelist.end()) {
/* Link to file. Process the link like the destination file. */
_tar_filelist.insert(TarFileList::value_type(src, dest_file->second));
} else {
/* Destination file not found. Assume 'link to directory'
* Append PATHSEPCHAR to 'src' and 'dest' if needed */
const std::string src_path = ((*src.rbegin() == PATHSEPCHAR) ? src : src + PATHSEPCHAR);
const std::string dst_path = (dest.length() == 0 ? "" : ((*dest.rbegin() == PATHSEPCHAR) ? dest : dest + PATHSEPCHAR));
_tar_linklist.insert(TarLinkList::value_type(src_path, dst_path));
}
}
void FioTarAddLink(const char *src, const char *dest)
{
TarAddLink(src, dest);
}
/**
* Simplify filenames from tars.
* Replace '/' by #PATHSEPCHAR, and force 'name' to lowercase.
* @param name Filename to process.
*/
static void SimplifyFileName(char *name)
{
/* Force lowercase */
strtolower(name);
/* Tar-files always have '/' path-seperator, but we want our PATHSEPCHAR */
#if (PATHSEPCHAR != '/')
for (char *n = name; *n != '\0'; n++) if (*n == '/') *n = PATHSEPCHAR;
#endif
}
/* static */ uint TarScanner::DoScan()
{
_tar_filelist.clear();
_tar_list.clear();
DEBUG(misc, 1, "Scanning for tars");
TarScanner fs;
uint num = fs.Scan(".tar", DATA_DIR, false);
num += fs.Scan(".tar", AI_DIR, false);
num += fs.Scan(".tar", AI_LIBRARY_DIR, false);
num += fs.Scan(".tar", SCENARIO_DIR, false);
DEBUG(misc, 1, "Scan complete, found %d files", num);
return num;
}
bool TarScanner::AddFile(const char *filename, size_t basepath_length)
{
/* The TAR-header, repeated for every file */
typedef struct TarHeader {
char name[100]; ///< Name of the file
char mode[8];
char uid[8];
char gid[8];
char size[12]; ///< Size of the file, in ASCII
char mtime[12];
char chksum[8];
char typeflag;
char linkname[100];
char magic[6];
char version[2];
char uname[32];
char gname[32];
char devmajor[8];
char devminor[8];
char prefix[155]; ///< Path of the file
char unused[12];
} TarHeader;
/* Check if we already seen this file */
TarList::iterator it = _tar_list.find(filename);
if (it != _tar_list.end()) return false;
FILE *f = fopen(filename, "rb");
/* Although the file has been found there can be
* a number of reasons we cannot open the file.
* Most common case is when we simply have not
* been given read access. */
if (f == NULL) return false;
const char *dupped_filename = strdup(filename);
_tar_list[filename].filename = dupped_filename;
_tar_list[filename].dirname = NULL;
TarLinkList links; ///< Temporary list to collect links
TarHeader th;
char buf[sizeof(th.name) + 1], *end;
char name[sizeof(th.prefix) + 1 + sizeof(th.name) + 1];
char link[sizeof(th.linkname) + 1];
char dest[sizeof(th.prefix) + 1 + sizeof(th.name) + 1 + 1 + sizeof(th.linkname) + 1];
size_t num = 0, pos = 0;
/* Make a char of 512 empty bytes */
char empty[512];
memset(&empty[0], 0, sizeof(empty));
for (;;) { // Note: feof() always returns 'false' after 'fseek()'. Cool, isn't it?
size_t num_bytes_read = fread(&th, 1, 512, f);
if (num_bytes_read != 512) break;
pos += num_bytes_read;
/* Check if we have the new tar-format (ustar) or the old one (a lot of zeros after 'link' field) */
if (strncmp(th.magic, "ustar", 5) != 0 && memcmp(&th.magic, &empty[0], 512 - offsetof(TarHeader, magic)) != 0) {
/* If we have only zeros in the block, it can be an end-of-file indicator */
if (memcmp(&th, &empty[0], 512) == 0) continue;
DEBUG(misc, 0, "The file '%s' isn't a valid tar-file", filename);
return false;
}
name[0] = '\0';
size_t len = 0;
/* The prefix contains the directory-name */
if (th.prefix[0] != '\0') {
memcpy(name, th.prefix, sizeof(th.prefix));
name[sizeof(th.prefix)] = '\0';
len = strlen(name);
name[len] = PATHSEPCHAR;
len++;
}
/* Copy the name of the file in a safe way at the end of 'name' */
memcpy(&name[len], th.name, sizeof(th.name));
name[len + sizeof(th.name)] = '\0';
/* Calculate the size of the file.. for some strange reason this is stored as a string */
memcpy(buf, th.size, sizeof(th.size));
buf[sizeof(th.size)] = '\0';
size_t skip = strtoul(buf, &end, 8);
switch (th.typeflag) {
case '\0':
case '0': { // regular file
/* Ignore empty files */
if (skip == 0) break;
if (strlen(name) == 0) break;
/* Store this entry in the list */
TarFileListEntry entry;
entry.tar_filename = dupped_filename;
entry.size = skip;
entry.position = pos;
/* Convert to lowercase and our PATHSEPCHAR */
SimplifyFileName(name);
DEBUG(misc, 6, "Found file in tar: %s (" PRINTF_SIZE " bytes, " PRINTF_SIZE " offset)", name, skip, pos);
if (_tar_filelist.insert(TarFileList::value_type(name, entry)).second) num++;
break;
}
case '1': // hard links
case '2': { // symbolic links
/* Copy the destination of the link in a safe way at the end of 'linkname' */
memcpy(link, th.linkname, sizeof(th.linkname));
link[sizeof(th.linkname)] = '\0';
if (strlen(name) == 0 || strlen(link) == 0) break;
/* Convert to lowercase and our PATHSEPCHAR */
SimplifyFileName(name);
SimplifyFileName(link);
/* Only allow relative links */
if (link[0] == PATHSEPCHAR) {
DEBUG(misc, 1, "Ignoring absolute link in tar: %s -> %s", name, link);
break;
}
/* Process relative path.
* Note: The destination of links must not contain any directory-links. */
strecpy(dest, name, lastof(dest));
char *destpos = strrchr(dest, PATHSEPCHAR);
if (destpos == NULL) destpos = dest;
*destpos = '\0';
char *pos = link;
while (*pos != '\0') {
char *next = strchr(link, PATHSEPCHAR);
if (next == NULL) next = pos + strlen(pos);
/* Skip '.' (current dir) */
if (next != pos + 1 || pos[0] != '.') {
if (next == pos + 2 && pos[0] == '.' && pos[1] == '.') {
/* level up */
if (dest[0] == '\0') {
DEBUG(misc, 1, "Ignoring link pointing outside of data directory: %s -> %s", name, link);
break;
}
/* Truncate 'dest' after last PATHSEPCHAR.
* This assumes that the truncated part is a real directory and not a link. */
destpos = strrchr(dest, PATHSEPCHAR);
if (destpos == NULL) destpos = dest;
} else {
/* Append at end of 'dest' */
if (destpos != dest) *(destpos++) = PATHSEPCHAR;
strncpy(destpos, pos, next - pos); // Safe as we do '\0'-termination ourselves
destpos += next - pos;
}
*destpos = '\0';
}
pos = next;
}
/* Store links in temporary list */
DEBUG(misc, 6, "Found link in tar: %s -> %s", name, dest);
links.insert(TarLinkList::value_type(name, dest));
break;
}
case '5': // directory
/* Convert to lowercase and our PATHSEPCHAR */
SimplifyFileName(name);
/* Store the first directory name we detect */
DEBUG(misc, 6, "Found dir in tar: %s", name);
if (_tar_list[filename].dirname == NULL) _tar_list[filename].dirname = strdup(name);
break;
default:
/* Ignore other types */
break;
}
/* Skip to the next block.. */
skip = Align(skip, 512);
fseek(f, skip, SEEK_CUR);
pos += skip;
}
DEBUG(misc, 1, "Found tar '%s' with " PRINTF_SIZE " new files", filename, num);
fclose(f);
/* Resolve file links and store directory links.
* We restrict usage of links to two cases:
* 1) Links to directories:
* Both the source path and the destination path must NOT contain any further links.
* When resolving files at most one directory link is resolved.
* 2) Links to files:
* The destination path must NOT contain any links.
* The source path may contain one directory link.
*/
for (TarLinkList::iterator link = links.begin(); link != links.end(); link++) {
const std::string &src = link->first;
const std::string &dest = link->second;
TarAddLink(src, dest);
}
return true;
}
/**
* Extract the tar with the given filename in the directory
* where the tar resides.
* @param tar_filename the name of the tar to extract.
* @return false on failure.
*/
bool ExtractTar(const char *tar_filename)
{
TarList::iterator it = _tar_list.find(tar_filename);
/* We don't know the file. */
if (it == _tar_list.end()) return false;
const char *dirname = (*it).second.dirname;
/* The file doesn't have a sub directory! */
if (dirname == NULL) return false;
char filename[MAX_PATH];
strecpy(filename, tar_filename, lastof(filename));
char *p = strrchr(filename, PATHSEPCHAR);
/* The file's path does not have a separator? */
if (p == NULL) return false;
p++;
strecpy(p, dirname, lastof(filename));
DEBUG(misc, 8, "Extracting %s to directory %s", tar_filename, filename);
FioCreateDirectory(filename);
for (TarFileList::iterator it2 = _tar_filelist.begin(); it2 != _tar_filelist.end(); it2++) {
if (strcmp((*it2).second.tar_filename, tar_filename) != 0) continue;
strecpy(p, (*it2).first.c_str(), lastof(filename));
DEBUG(misc, 9, " extracting %s", filename);
/* First open the file in the .tar. */
size_t to_copy = 0;
FILE *in = FioFOpenFileTar(&(*it2).second, &to_copy);
if (in == NULL) {
DEBUG(misc, 6, "Extracting %s failed; could not open %s", filename, tar_filename);
return false;
}
/* Now open the 'output' file. */
FILE *out = fopen(filename, "wb");
if (out == NULL) {
DEBUG(misc, 6, "Extracting %s failed; could not open %s", filename, filename);
fclose(in);
return false;
}
/* Now read from the tar and write it into the file. */
char buffer[4096];
size_t read;
for (; to_copy != 0; to_copy -= read) {
read = fread(buffer, 1, min(to_copy, lengthof(buffer)), in);
if (read <= 0 || fwrite(buffer, 1, read, out) != read) break;
}
/* Close everything up. */
fclose(in);
fclose(out);
if (to_copy != 0) {
DEBUG(misc, 6, "Extracting %s failed; still %i bytes to copy", filename, (int)to_copy);
return false;
}
}
DEBUG(misc, 9, " extraction successful");
return true;
}
#if defined(WIN32) || defined(WINCE)
/**
* Determine the base (personal dir and game data dir) paths
* @param exe the path from the current path to the executable
* @note defined in the OS related files (os2.cpp, win32.cpp, unix.cpp etc)
*/
extern void DetermineBasePaths(const char *exe);
#else /* defined(WIN32) || defined(WINCE) */
/**
* Changes the working directory to the path of the give executable.
* For OSX application bundles '.app' is the required extension of the bundle,
* so when we crop the path to there, when can remove the name of the bundle
* in the same way we remove the name from the executable name.
* @param exe the path to the executable
*/
static bool ChangeWorkingDirectoryToExecutable(const char *exe)
{
bool success = false;
#ifdef WITH_COCOA
char *app_bundle = strchr(exe, '.');
while (app_bundle != NULL && strncasecmp(app_bundle, ".app", 4) != 0) app_bundle = strchr(&app_bundle[1], '.');
if (app_bundle != NULL) app_bundle[0] = '\0';
#endif /* WITH_COCOA */
char *s = const_cast(strrchr(exe, PATHSEPCHAR));
if (s != NULL) {
*s = '\0';
#if defined(__DJGPP__)
/* If we want to go to the root, we can't use cd C:, but we must use '/' */
if (s[-1] == ':') chdir("/");
#endif
if (chdir(exe) != 0) {
DEBUG(misc, 0, "Directory with the binary does not exist?");
} else {
success = true;
}
*s = PATHSEPCHAR;
}
#ifdef WITH_COCOA
if (app_bundle != NULL) app_bundle[0] = '.';
#endif /* WITH_COCOA */
return success;
}
/**
* Whether we should scan the working directory.
* It should not be scanned if it's the root or
* the home directory as in both cases a big data
* directory can cause huge amounts of unrelated
* files scanned. Furthermore there are nearly no
* use cases for the home/root directory to have
* OpenTTD directories.
* @return true if it should be scanned.
*/
bool DoScanWorkingDirectory()
{
/* No working directory, so nothing to do. */
if (_searchpaths[SP_WORKING_DIR] == NULL) return false;
/* Working directory is root, so do nothing. */
if (strcmp(_searchpaths[SP_WORKING_DIR], PATHSEP) == 0) return false;
/* No personal/home directory, so the working directory won't be that. */
if (_searchpaths[SP_PERSONAL_DIR] == NULL) return true;
char tmp[MAX_PATH];
snprintf(tmp, lengthof(tmp), "%s%s", _searchpaths[SP_WORKING_DIR], PERSONAL_DIR);
AppendPathSeparator(tmp, MAX_PATH);
return strcmp(tmp, _searchpaths[SP_PERSONAL_DIR]) != 0;
}
/**
* Determine the base (personal dir and game data dir) paths
* @param exe the path to the executable
*/
void DetermineBasePaths(const char *exe)
{
char tmp[MAX_PATH];
#if defined(__MORPHOS__) || defined(__AMIGA__) || defined(DOS) || defined(OS2) || !defined(WITH_PERSONAL_DIR)
_searchpaths[SP_PERSONAL_DIR] = NULL;
#else
#ifdef __HAIKU__
BPath path;
find_directory(B_USER_SETTINGS_DIRECTORY, &path);
const char *homedir = path.Path();
#else
const char *homedir = getenv("HOME");
if (homedir == NULL) {
const struct passwd *pw = getpwuid(getuid());
homedir = (pw == NULL) ? "" : pw->pw_dir;
}
#endif
snprintf(tmp, MAX_PATH, "%s" PATHSEP "%s", homedir, PERSONAL_DIR);
AppendPathSeparator(tmp, MAX_PATH);
_searchpaths[SP_PERSONAL_DIR] = strdup(tmp);
#endif
#if defined(WITH_SHARED_DIR)
snprintf(tmp, MAX_PATH, "%s", SHARED_DIR);
AppendPathSeparator(tmp, MAX_PATH);
_searchpaths[SP_SHARED_DIR] = strdup(tmp);
#else
_searchpaths[SP_SHARED_DIR] = NULL;
#endif
#if defined(__MORPHOS__) || defined(__AMIGA__)
_searchpaths[SP_WORKING_DIR] = NULL;
#else
if (getcwd(tmp, MAX_PATH) == NULL) *tmp = '\0';
AppendPathSeparator(tmp, MAX_PATH);
_searchpaths[SP_WORKING_DIR] = strdup(tmp);
#endif
_do_scan_working_directory = DoScanWorkingDirectory();
/* Change the working directory to that one of the executable */
if (ChangeWorkingDirectoryToExecutable(exe)) {
if (getcwd(tmp, MAX_PATH) == NULL) *tmp = '\0';
AppendPathSeparator(tmp, MAX_PATH);
_searchpaths[SP_BINARY_DIR] = strdup(tmp);
} else {
_searchpaths[SP_BINARY_DIR] = NULL;
}
if (_searchpaths[SP_WORKING_DIR] != NULL) {
/* Go back to the current working directory. */
if (chdir(_searchpaths[SP_WORKING_DIR]) != 0) {
DEBUG(misc, 0, "Failed to return to working directory!");
}
}
#if defined(__MORPHOS__) || defined(__AMIGA__) || defined(DOS) || defined(OS2)
_searchpaths[SP_INSTALLATION_DIR] = NULL;
#else
snprintf(tmp, MAX_PATH, "%s", GLOBAL_DATA_DIR);
AppendPathSeparator(tmp, MAX_PATH);
_searchpaths[SP_INSTALLATION_DIR] = strdup(tmp);
#endif
#ifdef WITH_COCOA
extern void cocoaSetApplicationBundleDir();
cocoaSetApplicationBundleDir();
#else
_searchpaths[SP_APPLICATION_BUNDLE_DIR] = NULL;
#endif
}
#endif /* defined(WIN32) || defined(WINCE) */
char *_personal_dir;
/**
* Acquire the base paths (personal dir and game data dir),
* fill all other paths (save dir, autosave dir etc) and
* make the save and scenario directories.
* @param exe the path from the current path to the executable
*/
void DeterminePaths(const char *exe)
{
DetermineBasePaths(exe);
Searchpath sp;
FOR_ALL_SEARCHPATHS(sp) {
if (sp == SP_WORKING_DIR && !_do_scan_working_directory) continue;
DEBUG(misc, 4, "%s added as search path", _searchpaths[sp]);
}
if (_config_file != NULL) {
_personal_dir = strdup(_config_file);
char *end = strrchr(_personal_dir, PATHSEPCHAR);
if (end == NULL) {
_personal_dir[0] = '\0';
} else {
end[1] = '\0';
}
} else {
char personal_dir[MAX_PATH];
if (FioFindFullPath(personal_dir, lengthof(personal_dir), BASE_DIR, "openttd.cfg") != NULL) {
char *end = strrchr(personal_dir, PATHSEPCHAR);
if (end != NULL) end[1] = '\0';
_personal_dir = strdup(personal_dir);
_config_file = str_fmt("%sopenttd.cfg", _personal_dir);
} else {
static const Searchpath new_openttd_cfg_order[] = {
SP_PERSONAL_DIR, SP_BINARY_DIR, SP_WORKING_DIR, SP_SHARED_DIR, SP_INSTALLATION_DIR
};
for (uint i = 0; i < lengthof(new_openttd_cfg_order); i++) {
if (IsValidSearchPath(new_openttd_cfg_order[i])) {
_personal_dir = strdup(_searchpaths[new_openttd_cfg_order[i]]);
_config_file = str_fmt("%sopenttd.cfg", _personal_dir);
break;
}
}
}
}
DEBUG(misc, 3, "%s found as personal directory", _personal_dir);
_highscore_file = str_fmt("%shs.dat", _personal_dir);
extern char *_hotkeys_file;
_hotkeys_file = str_fmt("%shotkeys.cfg", _personal_dir);
/* Make the necessary folders */
#if !defined(__MORPHOS__) && !defined(__AMIGA__) && defined(WITH_PERSONAL_DIR)
FioCreateDirectory(_personal_dir);
#endif
static const Subdirectory default_subdirs[] = {
SAVE_DIR, AUTOSAVE_DIR, SCENARIO_DIR, HEIGHTMAP_DIR
};
for (uint i = 0; i < lengthof(default_subdirs); i++) {
char *dir = str_fmt("%s%s", _personal_dir, _subdirs[default_subdirs[i]]);
FioCreateDirectory(dir);
free(dir);
}
/* If we have network we make a directory for the autodownloading of content */
_searchpaths[SP_AUTODOWNLOAD_DIR] = str_fmt("%s%s", _personal_dir, "content_download" PATHSEP);
#ifdef ENABLE_NETWORK
FioCreateDirectory(_searchpaths[SP_AUTODOWNLOAD_DIR]);
/* Create the directory for each of the types of content */
const Subdirectory dirs[] = { SCENARIO_DIR, HEIGHTMAP_DIR, DATA_DIR, AI_DIR, AI_LIBRARY_DIR, GM_DIR };
for (uint i = 0; i < lengthof(dirs); i++) {
char *tmp = str_fmt("%s%s", _searchpaths[SP_AUTODOWNLOAD_DIR], _subdirs[dirs[i]]);
FioCreateDirectory(tmp);
free(tmp);
}
extern char *_log_file;
_log_file = str_fmt("%sopenttd.log", _personal_dir);
#else /* ENABLE_NETWORK */
/* If we don't have networking, we don't need to make the directory. But
* if it exists we keep it, otherwise remove it from the search paths. */
if (!FileExists(_searchpaths[SP_AUTODOWNLOAD_DIR])) {
free((void*)_searchpaths[SP_AUTODOWNLOAD_DIR]);
_searchpaths[SP_AUTODOWNLOAD_DIR] = NULL;
}
#endif /* ENABLE_NETWORK */
TarScanner::DoScan();
}
/**
* Sanitizes a filename, i.e. removes all illegal characters from it.
* @param filename the "\0" terminated filename
*/
void SanitizeFilename(char *filename)
{
for (; *filename != '\0'; filename++) {
switch (*filename) {
/* The following characters are not allowed in filenames
* on at least one of the supported operating systems: */
case ':': case '\\': case '*': case '?': case '/':
case '<': case '>': case '|': case '"':
*filename = '_';
break;
}
}
}
/**
* Load a file into memory.
* @param filename Name of the file to load.
* @param lenp [out] Length of loaded data.
* @param maxsize Maximum size to load.
* @return Pointer to new memory containing the loaded data, or \c NULL if loading failed.
* @note If \a maxsize less than the length of the file, loading fails.
*/
void *ReadFileToMem(const char *filename, size_t *lenp, size_t maxsize)
{
FILE *in = fopen(filename, "rb");
if (in == NULL) return NULL;
fseek(in, 0, SEEK_END);
size_t len = ftell(in);
fseek(in, 0, SEEK_SET);
if (len > maxsize) {
fclose(in);
return NULL;
}
byte *mem = MallocT(len + 1);
mem[len] = 0;
if (fread(mem, len, 1, in) != 1) {
fclose(in);
free(mem);
return NULL;
}
fclose(in);
*lenp = len;
return mem;
}
/**
* Scan a single directory (and recursively its children) and add
* any graphics sets that are found.
* @param fs the file scanner to add the files to
* @param extension the extension of files to search for.
* @param path full path we're currently at
* @param basepath_length from where in the path are we 'based' on the search path
* @param recursive whether to recursively search the sub directories
*/
static uint ScanPath(FileScanner *fs, const char *extension, const char *path, size_t basepath_length, bool recursive)
{
extern bool FiosIsValidFile(const char *path, const struct dirent *ent, struct stat *sb);
uint num = 0;
struct stat sb;
struct dirent *dirent;
DIR *dir;
if (path == NULL || (dir = ttd_opendir(path)) == NULL) return 0;
while ((dirent = readdir(dir)) != NULL) {
const char *d_name = FS2OTTD(dirent->d_name);
char filename[MAX_PATH];
if (!FiosIsValidFile(path, dirent, &sb)) continue;
snprintf(filename, lengthof(filename), "%s%s", path, d_name);
if (S_ISDIR(sb.st_mode)) {
/* Directory */
if (!recursive) continue;
if (strcmp(d_name, ".") == 0 || strcmp(d_name, "..") == 0) continue;
if (!AppendPathSeparator(filename, lengthof(filename))) continue;
num += ScanPath(fs, extension, filename, basepath_length, recursive);
} else if (S_ISREG(sb.st_mode)) {
/* File */
if (extension != NULL) {
char *ext = strrchr(filename, '.');
/* If no extension or extension isn't .grf, skip the file */
if (ext == NULL) continue;
if (strcasecmp(ext, extension) != 0) continue;
}
if (fs->AddFile(filename, basepath_length)) num++;
}
}
closedir(dir);
return num;
}
/**
* Scan the given tar and add graphics sets when it finds one.
* @param fs the file scanner to scan for
* @param extension the extension of files to search for.
* @param tar the tar to search in.
*/
static uint ScanTar(FileScanner *fs, const char *extension, TarFileList::iterator tar)
{
uint num = 0;
const char *filename = (*tar).first.c_str();
if (extension != NULL) {
const char *ext = strrchr(filename, '.');
/* If no extension or extension isn't .grf, skip the file */
if (ext == NULL) return false;
if (strcasecmp(ext, extension) != 0) return false;
}
if (fs->AddFile(filename, 0)) num++;
return num;
}
/**
* Scan for files with the given extention in the given search path.
* @param extension the extension of files to search for.
* @param sd the sub directory to search in.
* @param tars whether to search in the tars too.
* @param recursive whether to search recursively
* @return the number of found files, i.e. the number of times that
* AddFile returned true.
*/
uint FileScanner::Scan(const char *extension, Subdirectory sd, bool tars, bool recursive)
{
Searchpath sp;
char path[MAX_PATH];
TarFileList::iterator tar;
uint num = 0;
FOR_ALL_SEARCHPATHS(sp) {
/* Don't search in the working directory */
if (sp == SP_WORKING_DIR && !_do_scan_working_directory) continue;
FioAppendDirectory(path, MAX_PATH, sp, sd);
num += ScanPath(this, extension, path, strlen(path), recursive);
}
if (tars) {
FOR_ALL_TARS(tar) {
num += ScanTar(this, extension, tar);
}
}
return num;
}
/**
* Scan for files with the given extention in the given search path.
* @param extension the extension of files to search for.
* @param directory the sub directory to search in.
* @param recursive whether to search recursively
* @return the number of found files, i.e. the number of times that
* AddFile returned true.
*/
uint FileScanner::Scan(const char *extension, const char *directory, bool recursive)
{
char path[MAX_PATH];
strecpy(path, directory, lastof(path));
if (!AppendPathSeparator(path, lengthof(path))) return 0;
return ScanPath(this, extension, path, strlen(path), recursive);
}