newlib/winsup/cygwin/path.cc

4854 lines
142 KiB
C++

/* path.cc: path support.
Copyright 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005,
2006, 2007, 2008, 2009, 2010, 2011, 2012, 2013, 2014, 2015 Red Hat, Inc.
This file is part of Cygwin.
This software is a copyrighted work licensed under the terms of the
Cygwin license. Please consult the file "CYGWIN_LICENSE" for
details. */
/* This module's job is to
- convert between POSIX and Win32 style filenames,
- support the `mount' functionality,
- support symlinks for files and directories
Pathnames are handled as follows:
- A \ or : in a path denotes a pure windows spec.
- Paths beginning with // (or \\) are not translated (i.e. looked
up in the mount table) and are assumed to be UNC path names.
The goal in the above set of rules is to allow both POSIX and Win32
flavors of pathnames without either interfering. The rules are
intended to be as close to a superset of both as possible.
Note that you can have more than one path to a file. The mount
table is always prefered when translating Win32 paths to POSIX
paths. Win32 paths in mount table entries may be UNC paths or
standard Win32 paths starting with <drive-letter>:
Text vs Binary issues are not considered here in path style
decisions, although the appropriate flags are retrieved and
stored in various structures.
Removing mounted filesystem support would simplify things greatly,
but having it gives us a mechanism of treating disk that lives on a
UNIX machine as having UNIX semantics [it allows one to edit a text
file on that disk and not have cr's magically appear and perhaps
break apps running on UNIX boxes]. It also useful to be able to
layout a hierarchy without changing the underlying directories.
The semantics of mounting file systems is not intended to precisely
follow normal UNIX systems.
Each DOS drive is defined to have a current directory. Supporting
this would complicate things so for now things are defined so that
c: means c:\.
*/
/* This file includes both the XPG and GNU basename functions, with the
former exported as "basename" for ABI compatibility but the latter
declared as such for source compatibility with glibc. This tells
<string.h> not to declare the GNU variant in order to prevent a conflicting
declaration error with the XPG variant implemented herein. */
#define basename basename
#include "winsup.h"
#include "miscfuncs.h"
#include <ctype.h>
#include <winioctl.h>
#include <shlobj.h>
#include <sys/param.h>
#include <sys/cygwin.h>
#include "cygerrno.h"
#include "security.h"
#include "path.h"
#include "fhandler.h"
#include "dtable.h"
#include "cygheap.h"
#include "shared_info.h"
#include "cygtls.h"
#include "tls_pbuf.h"
#include "environ.h"
#include <assert.h>
#include <ntdll.h>
#include <wchar.h>
#include <wctype.h>
#undef basename
suffix_info stat_suffixes[] =
{
suffix_info ("", 1),
suffix_info (".exe", 1),
suffix_info (NULL)
};
struct symlink_info
{
char contents[SYMLINK_MAX + 1];
char *ext_here;
int extn;
unsigned pflags;
DWORD fileattr;
int issymlink;
bool ext_tacked_on;
int error;
bool isdevice;
_major_t major;
_minor_t minor;
_mode_t mode;
int check (char *path, const suffix_info *suffixes, fs_info &fs,
path_conv_handle &conv_hdl);
int set (char *path);
bool parse_device (const char *);
int check_sysfile (HANDLE h);
int check_shortcut (HANDLE h);
int check_reparse_point (HANDLE h, bool remote);
int check_nfs_symlink (HANDLE h);
int posixify (char *srcbuf);
bool set_error (int);
};
muto NO_COPY cwdstuff::cwd_lock;
static const GUID GUID_shortcut
= { 0x00021401L, 0, 0, {0xc0, 0, 0, 0, 0, 0, 0, 0x46}};
enum
{
WSH_FLAG_IDLIST = 0x01, /* Contains an ITEMIDLIST. */
WSH_FLAG_FILE = 0x02, /* Contains a file locator element. */
WSH_FLAG_DESC = 0x04, /* Contains a description. */
WSH_FLAG_RELPATH = 0x08, /* Contains a relative path. */
WSH_FLAG_WD = 0x10, /* Contains a working dir. */
WSH_FLAG_CMDLINE = 0x20, /* Contains command line args. */
WSH_FLAG_ICON = 0x40 /* Contains a custom icon. */
};
struct win_shortcut_hdr
{
DWORD size; /* Header size in bytes. Must contain 0x4c. */
GUID magic; /* GUID of shortcut files. */
DWORD flags; /* Content flags. See above. */
/* The next fields from attr to icon_no are always set to 0 in Cygwin
and U/Win shortcuts. */
DWORD attr; /* Target file attributes. */
FILETIME ctime; /* These filetime items are never touched by the */
FILETIME mtime; /* system, apparently. Values don't matter. */
FILETIME atime;
DWORD filesize; /* Target filesize. */
DWORD icon_no; /* Icon number. */
DWORD run; /* Values defined in winuser.h. Use SW_NORMAL. */
DWORD hotkey; /* Hotkey value. Set to 0. */
DWORD dummy[2]; /* Future extension probably. Always 0. */
};
/* Return non-zero if PATH1 is a prefix of PATH2.
Both are assumed to be of the same path style and / vs \ usage.
Neither may be "".
LEN1 = strlen (PATH1). It's passed because often it's already known.
Examples:
/foo/ is a prefix of /foo <-- may seem odd, but desired
/foo is a prefix of /foo/
/ is a prefix of /foo/bar
/ is not a prefix of foo/bar
foo/ is a prefix foo/bar
/foo is not a prefix of /foobar
*/
int
path_prefix_p (const char *path1, const char *path2, int len1,
bool caseinsensitive)
{
/* Handle case where PATH1 has trailing '/' and when it doesn't. */
if (len1 > 0 && isdirsep (path1[len1 - 1]))
len1--;
if (len1 == 0)
return isdirsep (path2[0]) && !isdirsep (path2[1]);
if (isdirsep (path2[len1]) || path2[len1] == 0 || path1[len1 - 1] == ':')
return caseinsensitive ? strncasematch (path1, path2, len1)
: !strncmp (path1, path2, len1);
return 0;
}
/* Return non-zero if paths match in first len chars.
Check is dependent of the case sensitivity setting. */
int
pathnmatch (const char *path1, const char *path2, int len, bool caseinsensitive)
{
return caseinsensitive
? strncasematch (path1, path2, len) : !strncmp (path1, path2, len);
}
/* Return non-zero if paths match. Check is dependent of the case
sensitivity setting. */
int
pathmatch (const char *path1, const char *path2, bool caseinsensitive)
{
return caseinsensitive
? strcasematch (path1, path2) : !strcmp (path1, path2);
}
/* TODO: This function is used in mkdir and rmdir to generate correct
error messages in case of paths ending in /. or /.. components.
Right now, normalize_posix_path will just normalize
those components away, which changes the semantics. */
bool
has_dot_last_component (const char *dir, bool test_dot_dot)
{
/* SUSv3: . and .. are not allowed as last components in various system
calls. Don't test for backslash path separator since that's a Win32
path following Win32 rules. */
const char *last_comp = strchr (dir, '\0');
if (last_comp == dir)
return false; /* Empty string. Probably shouldn't happen here? */
/* Detect run of trailing slashes */
while (last_comp > dir && *--last_comp == '/')
continue;
/* Detect just a run of slashes or a path that does not end with a slash. */
if (*last_comp != '.')
return false;
/* We know we have a trailing dot here. Check that it really is a standalone "."
path component by checking that it is at the beginning of the string or is
preceded by a "/" */
if (last_comp == dir || *--last_comp == '/')
return true;
/* If we're not checking for '..' we're done. Ditto if we're now pointing to
a non-dot. */
if (!test_dot_dot || *last_comp != '.')
return false; /* either not testing for .. or this was not '..' */
/* Repeat previous test for standalone or path component. */
return last_comp == dir || last_comp[-1] == '/';
}
/* Normalize a POSIX path.
All duplicate /'s, except for 2 leading /'s, are deleted.
The result is 0 for success, or an errno error value. */
int
normalize_posix_path (const char *src, char *dst, char *&tail)
{
const char *in_src = src;
char *dst_start = dst;
bool check_parent = false;
syscall_printf ("src %s", src);
if ((isdrive (src) && isdirsep (src[2])) || *src == '\\')
goto win32_path;
tail = dst;
if (!isslash (src[0]))
{
if (!cygheap->cwd.get (dst))
return get_errno ();
tail = strchr (tail, '\0');
if (isslash (dst[0]) && isslash (dst[1]))
++dst_start;
if (*src == '.')
{
if (tail == dst_start + 1 && *dst_start == '/')
tail--;
goto sawdot;
}
if (tail > dst && !isslash (tail[-1]))
*tail++ = '/';
}
/* Two leading /'s? If so, preserve them. */
else if (isslash (src[1]) && !isslash (src[2]))
{
*tail++ = *src++;
++dst_start;
}
while (*src)
{
if (*src == '\\')
goto win32_path;
/* Strip runs of /'s. */
if (!isslash (*src))
*tail++ = *src++;
else
{
check_parent = true;
while (*++src)
{
if (isslash (*src))
continue;
if (*src != '.')
break;
sawdot:
if (src[1] != '.')
{
if (!src[1])
{
*tail++ = '/';
goto done;
}
if (!isslash (src[1]))
break;
}
else if (src[2] && !isslash (src[2]))
break;
else
{
/* According to POSIX semantics all elements of path must
exist. To follow it, we must validate our path before
removing the trailing component. Check_parent is needed
for performance optimization, in order not to verify paths
which are already verified. For example this prevents
double check in case of foo/bar/../.. */
if (check_parent)
{
if (tail > dst_start) /* Don't check for / or // dir. */
{
*tail = 0;
debug_printf ("checking %s before '..'", dst);
/* In conjunction with native and NFS symlinks,
this call can result in a recursion which eats
up our tmp_pathbuf buffers. This in turn results
in a api_fatal call. To avoid that, we're
checking our remaining buffers and return an
error code instead. Note that this only happens
if the path contains 15 or more relative native/NFS
symlinks with a ".." in the target path. */
tmp_pathbuf tp;
if (!tp.check_usage (4, 3))
return ELOOP;
path_conv head (dst, PC_SYM_FOLLOW | PC_POSIX);
if (!head.isdir())
return ENOENT;
/* At this point, dst is a normalized path. If the
normalized path created by path_conv does not
match the normalized path we're just testing, then
the path in dst contains native symlinks. If we
just plunge along, removing the previous path
component, we may end up removing a symlink from
the path and the resulting path will be invalid.
So we replace dst with what we found in head
instead. All the work replacing symlinks has been
done in that path anyway, so why repeat it? */
tail = stpcpy (dst, head.get_posix ());
}
check_parent = false;
}
while (tail > dst_start && !isslash (*--tail))
continue;
src++;
}
}
*tail++ = '/';
}
if ((tail - dst) >= NT_MAX_PATH)
{
debug_printf ("ENAMETOOLONG = normalize_posix_path (%s)", src);
return ENAMETOOLONG;
}
}
done:
*tail = '\0';
debug_printf ("%s = normalize_posix_path (%s)", dst, in_src);
return 0;
win32_path:
int err = normalize_win32_path (in_src, dst, tail);
if (!err)
for (char *p = dst; (p = strchr (p, '\\')); p++)
*p = '/';
return err ?: -1;
}
inline void
path_conv::add_ext_from_sym (symlink_info &sym)
{
if (sym.ext_here && *sym.ext_here)
{
suffix = path + sym.extn;
if (sym.ext_tacked_on)
strcpy ((char *) suffix, sym.ext_here);
}
}
static void __reg2 mkrelpath (char *dst, bool caseinsensitive);
static void __reg2
mkrelpath (char *path, bool caseinsensitive)
{
tmp_pathbuf tp;
char *cwd_win32 = tp.c_get ();
if (!cygheap->cwd.get (cwd_win32, 0))
return;
unsigned cwdlen = strlen (cwd_win32);
if (!path_prefix_p (cwd_win32, path, cwdlen, caseinsensitive))
return;
size_t n = strlen (path);
if (n < cwdlen)
return;
char *tail = path;
if (n == cwdlen)
tail += cwdlen;
else
tail += isdirsep (cwd_win32[cwdlen - 1]) ? cwdlen : cwdlen + 1;
memmove (path, tail, strlen (tail) + 1);
if (!*path)
strcpy (path, ".");
}
void
path_conv::set_posix (const char *path_copy)
{
if (path_copy)
{
size_t n = strlen (path_copy) + 1;
char *p = (char *) crealloc_abort ((void *) posix_path, n);
posix_path = (const char *) memcpy (p, path_copy, n);
}
}
static inline void
str2uni_cat (UNICODE_STRING &tgt, const char *srcstr)
{
int len = sys_mbstowcs (tgt.Buffer + tgt.Length / sizeof (WCHAR),
(tgt.MaximumLength - tgt.Length) / sizeof (WCHAR),
srcstr);
if (len)
tgt.Length += (len - 1) * sizeof (WCHAR);
}
PUNICODE_STRING
get_nt_native_path (const char *path, UNICODE_STRING& upath, bool dos)
{
upath.Length = 0;
if (path[0] == '/') /* special path w/o NT path representation. */
str2uni_cat (upath, path);
else if (path[0] != '\\') /* X:\... or relative path. */
{
if (path[1] == ':') /* X:\... */
{
RtlAppendUnicodeStringToString (&upath, &ro_u_natp);
str2uni_cat (upath, path);
/* The drive letter must be upper case. */
upath.Buffer[4] = towupper (upath.Buffer[4]);
}
else
str2uni_cat (upath, path);
transform_chars (&upath, 7);
}
else if (path[1] != '\\') /* \Device\... */
str2uni_cat (upath, path);
else if ((path[2] != '.' && path[2] != '?')
|| path[3] != '\\') /* \\server\share\... */
{
RtlAppendUnicodeStringToString (&upath, &ro_u_uncp);
str2uni_cat (upath, path + 2);
transform_chars (&upath, 8);
}
else /* \\.\device or \\?\foo */
{
RtlAppendUnicodeStringToString (&upath, &ro_u_natp);
str2uni_cat (upath, path + 4);
}
if (dos)
{
/* Unfortunately we can't just use transform_chars with the tfx_rev_chars
table since only leading and trailing spaces and dots are affected.
So we step to every backslash and fix surrounding dots and spaces.
That makes these broken filesystems a bit slower, but, hey. */
PWCHAR cp = upath.Buffer + 7;
PWCHAR cend = upath.Buffer + upath.Length / sizeof (WCHAR);
while (++cp < cend)
if (*cp == L'\\')
{
PWCHAR ccp = cp - 1;
while (*ccp == L'.' || *ccp == L' ')
*ccp-- |= 0xf000;
while (cp[1] == L' ')
*++cp |= 0xf000;
}
while (*--cp == L'.' || *cp == L' ')
*cp |= 0xf000;
}
return &upath;
}
/* Handle with extrem care! Only used in a certain instance in try_to_bin.
Every other usage needs a careful check. */
void
path_conv::set_nt_native_path (PUNICODE_STRING new_path)
{
wide_path = (PWCHAR) crealloc_abort (wide_path, new_path->MaximumLength);
memcpy (wide_path, new_path->Buffer, new_path->Length);
uni_path.Length = new_path->Length;
uni_path.MaximumLength = new_path->MaximumLength;
uni_path.Buffer = wide_path;
}
PUNICODE_STRING
path_conv::get_nt_native_path ()
{
PUNICODE_STRING res;
if (wide_path)
res = &uni_path;
else if (!path)
res = NULL;
else
{
uni_path.Length = 0;
uni_path.MaximumLength = (strlen (path) + 10) * sizeof (WCHAR);
wide_path = (PWCHAR) cmalloc_abort (HEAP_STR, uni_path.MaximumLength);
uni_path.Buffer = wide_path;
::get_nt_native_path (path, uni_path, has_dos_filenames_only ());
res = &uni_path;
}
return res;
}
PWCHAR
path_conv::get_wide_win32_path (PWCHAR wc)
{
get_nt_native_path ();
if (!wide_path)
return NULL;
wcpcpy (wc, wide_path);
if (wc[1] == L'?')
wc[1] = L'\\';
return wc;
}
static void
warn_msdos (const char *src)
{
if (user_shared->warned_msdos || !cygwin_finished_initializing)
return;
tmp_pathbuf tp;
char *posix_path = tp.c_get ();
small_printf ("Cygwin WARNING:\n");
if (cygwin_conv_path (CCP_WIN_A_TO_POSIX | CCP_RELATIVE, src,
posix_path, NT_MAX_PATH))
small_printf (
" MS-DOS style path detected: %ls\n POSIX equivalent preferred.\n",
src);
else
small_printf (
" MS-DOS style path detected: %ls\n"
" Preferred POSIX equivalent is: %ls\n",
src, posix_path);
small_printf (
" CYGWIN environment variable option \"nodosfilewarning\" turns off this\n"
" warning. Consult the user's guide for more details about POSIX paths:\n"
" http://cygwin.com/cygwin-ug-net/using.html#using-pathnames\n");
user_shared->warned_msdos = true;
}
static DWORD
getfileattr (const char *path, bool caseinsensitive) /* path has to be always absolute. */
{
tmp_pathbuf tp;
UNICODE_STRING upath;
OBJECT_ATTRIBUTES attr;
FILE_BASIC_INFORMATION fbi;
NTSTATUS status;
IO_STATUS_BLOCK io;
tp.u_get (&upath);
InitializeObjectAttributes (&attr, &upath,
caseinsensitive ? OBJ_CASE_INSENSITIVE : 0,
NULL, NULL);
get_nt_native_path (path, upath, false);
status = NtQueryAttributesFile (&attr, &fbi);
if (NT_SUCCESS (status))
return fbi.FileAttributes;
if (status != STATUS_OBJECT_NAME_NOT_FOUND
&& status != STATUS_NO_SUCH_FILE) /* File not found on 9x share */
{
/* File exists but access denied. Try to get attribute through
directory query. */
UNICODE_STRING dirname, basename;
HANDLE dir;
FILE_BOTH_DIR_INFORMATION fdi;
RtlSplitUnicodePath (&upath, &dirname, &basename);
InitializeObjectAttributes (&attr, &dirname,
caseinsensitive ? OBJ_CASE_INSENSITIVE : 0,
NULL, NULL);
status = NtOpenFile (&dir, SYNCHRONIZE | FILE_LIST_DIRECTORY,
&attr, &io, FILE_SHARE_VALID_FLAGS,
FILE_SYNCHRONOUS_IO_NONALERT
| FILE_OPEN_FOR_BACKUP_INTENT
| FILE_DIRECTORY_FILE);
if (NT_SUCCESS (status))
{
status = NtQueryDirectoryFile (dir, NULL, NULL, 0, &io,
&fdi, sizeof fdi,
FileBothDirectoryInformation,
TRUE, &basename, TRUE);
NtClose (dir);
if (NT_SUCCESS (status) || status == STATUS_BUFFER_OVERFLOW)
return fdi.FileAttributes;
}
}
SetLastError (RtlNtStatusToDosError (status));
return INVALID_FILE_ATTRIBUTES;
}
/* Convert an arbitrary path SRC to a pure Win32 path, suitable for
passing to Win32 API routines.
If an error occurs, `error' is set to the errno value.
Otherwise it is set to 0.
follow_mode values:
SYMLINK_FOLLOW - convert to PATH symlink points to
SYMLINK_NOFOLLOW - convert to PATH of symlink itself
SYMLINK_IGNORE - do not check PATH for symlinks
SYMLINK_CONTENTS - just return symlink contents
*/
/* TODO: This implementation is only preliminary. For internal
purposes it's necessary to have a path_conv::check function which
takes a UNICODE_STRING src path, otherwise we waste a lot of time
for converting back and forth. The below implementation does
realy nothing but converting to char *, until path_conv handles
wide-char paths directly. */
void
path_conv::check (const UNICODE_STRING *src, unsigned opt,
const suffix_info *suffixes)
{
tmp_pathbuf tp;
char *path = tp.c_get ();
user_shared->warned_msdos = true;
sys_wcstombs (path, NT_MAX_PATH, src->Buffer, src->Length / sizeof (WCHAR));
path_conv::check (path, opt, suffixes);
}
void
path_conv::check (const char *src, unsigned opt,
const suffix_info *suffixes)
{
/* The tmp_buf array is used when expanding symlinks. It is NT_MAX_PATH * 2
in length so that we can hold the expanded symlink plus a trailer. */
tmp_pathbuf tp;
char *path_copy = tp.c_get ();
char *pathbuf = tp.c_get ();
char *tmp_buf = tp.t_get ();
char *THIS_path = tp.c_get ();
symlink_info sym;
bool need_directory = 0;
bool saw_symlinks = 0;
bool add_ext = false;
bool is_relpath;
char *tail, *path_end;
#if 0
static path_conv last_path_conv;
static char last_src[CYG_MAX_PATH];
if (*last_src && strcmp (last_src, src) == 0)
{
*this = last_path_conv;
return;
}
#endif
__try
{
int loop = 0;
path_flags = 0;
suffix = NULL;
fileattr = INVALID_FILE_ATTRIBUTES;
caseinsensitive = OBJ_CASE_INSENSITIVE;
if (wide_path)
cfree (wide_path);
wide_path = NULL;
if (path)
{
cfree (modifiable_path ());
path = NULL;
}
close_conv_handle ();
memset (&dev, 0, sizeof (dev));
fs.clear ();
if (posix_path)
{
cfree ((void *) posix_path);
posix_path = NULL;
}
int component = 0; // Number of translated components
if (!(opt & PC_NULLEMPTY))
error = 0;
else if (!*src)
{
error = ENOENT;
return;
}
bool is_msdos = false;
/* This loop handles symlink expansion. */
for (;;)
{
MALLOC_CHECK;
assert (src);
is_relpath = !isabspath (src);
error = normalize_posix_path (src, path_copy, tail);
if (error > 0)
return;
if (error < 0)
{
if (component == 0)
is_msdos = true;
error = 0;
}
/* Detect if the user was looking for a directory. We have to strip
the trailing slash initially while trying to add extensions but
take it into account during processing */
if (tail > path_copy + 2 && isslash (tail[-1]))
{
need_directory = 1;
*--tail = '\0';
}
path_end = tail;
/* Scan path_copy from right to left looking either for a symlink
or an actual existing file. If an existing file is found, just
return. If a symlink is found, exit the for loop.
Also: be careful to preserve the errno returned from
symlink.check as the caller may need it. */
/* FIXME: Do we have to worry about multiple \'s here? */
component = 0; // Number of translated components
sym.contents[0] = '\0';
int symlen = 0;
for (unsigned pflags_or = opt & (PC_NO_ACCESS_CHECK | PC_KEEP_HANDLE);
;
pflags_or = 0)
{
const suffix_info *suff;
char *full_path;
/* Don't allow symlink.check to set anything in the path_conv
class if we're working on an inner component of the path */
if (component)
{
suff = NULL;
full_path = pathbuf;
}
else
{
suff = suffixes;
full_path = THIS_path;
}
retry_fs_via_processfd:
/* Convert to native path spec sans symbolic link info. */
error = mount_table->conv_to_win32_path (path_copy, full_path,
dev, &sym.pflags);
if (error)
return;
sym.pflags |= pflags_or;
if (!dev.exists ())
{
error = ENXIO;
return;
}
if (iscygdrive_dev (dev))
{
if (!component)
fileattr = FILE_ATTRIBUTE_DIRECTORY
| FILE_ATTRIBUTE_READONLY;
else
{
fileattr = getfileattr (THIS_path,
sym.pflags & MOUNT_NOPOSIX);
dev = FH_FS;
}
goto out;
}
else if (isdev_dev (dev))
{
/* Make sure that the path handling goes on as with FH_FS. */
}
else if (isvirtual_dev (dev))
{
/* FIXME: Calling build_fhandler here is not the right way to
handle this. */
fhandler_virtual *fh = (fhandler_virtual *)
build_fh_dev (dev, path_copy);
virtual_ftype_t file_type;
if (!fh)
file_type = virt_none;
else
{
file_type = fh->exists ();
if (file_type == virt_symlink)
{
fh->fill_filebuf ();
symlen = sym.set (fh->get_filebuf ());
}
else if (file_type == virt_fsdir && dev == FH_PROCESS)
{
/* FIXME: This is YA bad hack to workaround that
we're checking for isvirtual_dev at this point.
This should only happen if the file is actually
a virtual file, and NOT already if the preceeding
path components constitute a virtual file.
Anyway, what we do here is this: If the descriptor
symlink points to a dir, and if there are trailing
path components, it's actually pointing somewhere
else. The format_process_fd function returns the
full path, resolved symlink plus trailing path
components, in its filebuf. This is a POSIX path
we know nothing about, so we have to convert it to
native again, calling conv_to_win32_path. Since
basically nothing happened yet, just copy it over
into full_path and jump back to the
conv_to_win32_path call. What a mess. */
stpcpy (path_copy, fh->get_filebuf ());
delete fh;
goto retry_fs_via_processfd;
}
delete fh;
}
switch (file_type)
{
case virt_directory:
case virt_rootdir:
if (component == 0)
fileattr = FILE_ATTRIBUTE_DIRECTORY;
break;
case virt_file:
if (component == 0)
fileattr = 0;
break;
case virt_symlink:
goto is_virtual_symlink;
case virt_pipe:
if (component == 0)
{
fileattr = 0;
dev.parse (FH_PIPE);
}
break;
case virt_socket:
if (component == 0)
{
fileattr = 0;
dev.parse (FH_TCP);
}
break;
case virt_fsdir:
case virt_fsfile:
/* Access to real file or directory via block device
entry in /proc/sys. Convert to real file and go with
the flow. */
dev.parse (FH_FS);
goto is_fs_via_procsys;
case virt_blk:
/* Block special device. If the trailing slash has been
requested, the target is the root directory of the
filesystem on this block device. So we convert this
to a real file and attach the backslash. */
if (component == 0 && need_directory)
{
dev.parse (FH_FS);
strcat (full_path, "\\");
fileattr = FILE_ATTRIBUTE_DIRECTORY
| FILE_ATTRIBUTE_DEVICE;
goto out;
}
/*FALLTHRU*/
case virt_chr:
if (component == 0)
fileattr = FILE_ATTRIBUTE_DEVICE;
break;
default:
if (component == 0)
fileattr = INVALID_FILE_ATTRIBUTES;
goto virtual_component_retry;
}
if (component == 0 || dev != FH_NETDRIVE)
path_flags |= PATH_RO;
goto out;
}
/* devn should not be a device. If it is, then stop parsing. */
else if (dev != FH_FS)
{
fileattr = 0;
path_flags = sym.pflags;
if (component)
{
error = ENOTDIR;
return;
}
goto out; /* Found a device. Stop parsing. */
}
/* If path is only a drivename, Windows interprets it as the
current working directory on this drive instead of the root
dir which is what we want. So we need the trailing backslash
in this case. */
if (full_path[0] && full_path[1] == ':' && full_path[2] == '\0')
{
full_path[2] = '\\';
full_path[3] = '\0';
}
/* If the incoming path was given in DOS notation, always treat
it as caseinsensitive,noacl path. This must be set before
calling sym.check, otherwise the path is potentially treated
casesensitive. */
if (is_msdos)
sym.pflags |= PATH_NOPOSIX | PATH_NOACL;
is_fs_via_procsys:
symlen = sym.check (full_path, suff, fs, conv_handle);
is_virtual_symlink:
if (sym.isdevice)
{
if (component)
{
error = ENOTDIR;
return;
}
dev.parse (sym.major, sym.minor);
dev.setfs (1);
dev.mode = sym.mode;
fileattr = sym.fileattr;
goto out;
}
if (sym.pflags & PATH_SOCKET)
{
if (component)
{
error = ENOTDIR;
return;
}
fileattr = sym.fileattr;
dev.parse (FH_UNIX);
dev.setfs (1);
goto out;
}
if (!component)
{
/* Make sure that /dev always exists. */
fileattr = isdev_dev (dev) ? FILE_ATTRIBUTE_DIRECTORY
: sym.fileattr;
path_flags = sym.pflags;
}
else if (isdev_dev (dev))
{
/* If we're looking for a non-existing file below /dev,
make sure that the device type is converted to FH_FS, so
that subsequent code handles the file correctly. Unless
/dev itself doesn't exist on disk. In that case /dev
is handled as virtual filesystem, and virtual filesystems
are read-only. The PC_KEEP_HANDLE check allows to check
for a call from an informational system call. In that
case we just stick to ENOENT, and the device type doesn't
matter anyway. */
if (sym.error == ENOENT && !(opt & PC_KEEP_HANDLE))
sym.error = EROFS;
else
dev = FH_FS;
}
/* If symlink.check found an existing non-symlink file, then
it sets the appropriate flag. It also sets any suffix found
into `ext_here'. */
if (!sym.issymlink && sym.fileattr != INVALID_FILE_ATTRIBUTES)
{
error = sym.error;
if (component == 0)
add_ext = true;
else if (!(sym.fileattr & FILE_ATTRIBUTE_DIRECTORY))
{
error = ENOTDIR;
goto out;
}
goto out; // file found
}
/* Found a symlink if symlen > 0. If component == 0, then the
src path itself was a symlink. If !follow_mode then
we're done. Otherwise we have to insert the path found
into the full path that we are building and perform all of
these operations again on the newly derived path. */
else if (symlen > 0)
{
saw_symlinks = 1;
if (component == 0 && !need_directory
&& (!(opt & PC_SYM_FOLLOW)
|| (is_rep_symlink ()
&& (opt & PC_SYM_NOFOLLOW_REP))))
{
/* last component of path is a symlink. */
set_symlink (symlen);
if (opt & PC_SYM_CONTENTS)
{
strcpy (THIS_path, sym.contents);
goto out;
}
add_ext = true;
goto out;
}
/* Following a symlink we can't trust the collected
filesystem information any longer. */
fs.clear ();
/* Close handle, if we have any. Otherwise we're collecting
handles while following symlinks. */
conv_handle.close ();
break;
}
else if (sym.error && sym.error != ENOENT)
{
error = sym.error;
goto out;
}
/* No existing file found. */
virtual_component_retry:
/* Find the new "tail" of the path, e.g. in '/for/bar/baz',
/baz is the tail. */
if (tail != path_end)
*tail = '/';
while (--tail > path_copy + 1 && *tail != '/') {}
/* Exit loop if there is no tail or we are at the
beginning of a UNC path */
if (tail <= path_copy + 1)
goto out; // all done
/* Haven't found an existing pathname component yet.
Pinch off the tail and try again. */
*tail = '\0';
component++;
}
/* Arrive here if above loop detected a symlink. */
if (++loop > SYMLOOP_MAX)
{
error = ELOOP; // Eep.
return;
}
MALLOC_CHECK;
/* Place the link content, possibly with head and/or tail,
in tmp_buf */
char *headptr;
if (isabspath (sym.contents))
headptr = tmp_buf; /* absolute path */
else
{
/* Copy the first part of the path (with ending /) and point to
the end. */
char *prevtail = tail;
while (--prevtail > path_copy && *prevtail != '/') {}
int headlen = prevtail - path_copy + 1;;
memcpy (tmp_buf, path_copy, headlen);
headptr = &tmp_buf[headlen];
}
/* Make sure there is enough space */
if (headptr + symlen >= tmp_buf + (2 * NT_MAX_PATH))
{
too_long:
error = ENAMETOOLONG;
set_path ("::ENAMETOOLONG::");
return;
}
/* Copy the symlink contents to the end of tmp_buf.
Convert slashes. */
for (char *p = sym.contents; *p; p++)
*headptr++ = *p == '\\' ? '/' : *p;
*headptr = '\0';
/* Copy any tail component (with the 0) */
if (tail++ < path_end)
{
/* Add a slash if needed. There is space. */
if (*(headptr - 1) != '/')
*headptr++ = '/';
int taillen = path_end - tail + 1;
if (headptr + taillen > tmp_buf + (2 * NT_MAX_PATH))
goto too_long;
memcpy (headptr, tail, taillen);
}
/* Evaluate everything all over again. */
src = tmp_buf;
}
if (!(opt & PC_SYM_CONTENTS))
add_ext = true;
out:
set_path (THIS_path);
if (add_ext)
add_ext_from_sym (sym);
if (dev == FH_NETDRIVE && component)
{
/* This case indicates a non-existant resp. a non-retrievable
share. This happens for instance if the share is a printer.
In this case the path must not be treated like a FH_NETDRIVE,
but like a FH_FS instead, so the usual open call for files
is used on it. */
dev.parse (FH_FS);
}
else if (isproc_dev (dev) && fileattr == INVALID_FILE_ATTRIBUTES)
{
/* FIXME: Usually we don't set error to ENOENT if a file doesn't
exist. This is typically indicated by the fileattr content.
So, why here? The downside is that cygwin_conv_path just gets
an error for these paths so it reports the error back to the
application. Unlike in all other cases of non-existant files,
for which check doesn't set error, so cygwin_conv_path just
returns the path, as intended. */
error = ENOENT;
return;
}
else if (!need_directory || error)
/* nothing to do */;
else if (fileattr == INVALID_FILE_ATTRIBUTES)
/* Reattach trailing dirsep in native path. */
strcat (modifiable_path (), "\\");
else if (fileattr & FILE_ATTRIBUTE_DIRECTORY)
path_flags &= ~PATH_SYMLINK;
else
{
debug_printf ("%s is a non-directory", path);
error = ENOTDIR;
return;
}
if (dev.isfs ())
{
if (strncmp (path, "\\\\.\\", 4))
{
if (!tail || tail == path)
/* nothing */;
else if (tail[-1] != '\\')
*tail = '\0';
else
{
error = ENOENT;
return;
}
}
/* If FS hasn't been checked already in symlink_info::check,
do so now. */
if (fs.inited ()|| fs.update (get_nt_native_path (), NULL))
{
/* Incoming DOS paths are treated like DOS paths in native
Windows applications. No ACLs, just default settings. */
if (is_msdos)
fs.has_acls (false);
debug_printf ("this->path(%s), has_acls(%d)",
path, fs.has_acls ());
/* CV: We could use this->has_acls() but I want to make sure that
we don't forget that the PATH_NOACL flag must be taken into
account here. */
if (!(path_flags & PATH_NOACL) && fs.has_acls ())
set_exec (0); /* We really don't know if this is executable or
not here but set it to not executable since
it will be figured out later by anything
which cares about this. */
}
/* If the FS has been found to have unrelibale inodes, note
that in path_flags. */
if (!fs.hasgood_inode ())
path_flags |= PATH_IHASH;
/* If the OS is caseinsensitive or the FS is caseinsensitive,
don't handle path casesensitive. */
if (cygwin_shared->obcaseinsensitive || fs.caseinsensitive ())
path_flags |= PATH_NOPOSIX;
caseinsensitive = (path_flags & PATH_NOPOSIX)
? OBJ_CASE_INSENSITIVE : 0;
if (exec_state () != dont_know_if_executable)
/* ok */;
else if (isdir ())
set_exec (1);
else if (issymlink () || issocket ())
set_exec (0);
}
if (opt & PC_NOFULL)
{
if (is_relpath)
{
mkrelpath (this->modifiable_path (), !!caseinsensitive);
/* Invalidate wide_path so that wide relpath can be created
in later calls to get_nt_native_path or get_wide_win32_path. */
if (wide_path)
cfree (wide_path);
wide_path = NULL;
}
if (need_directory)
{
size_t n = strlen (this->path);
/* Do not add trailing \ to UNC device names like \\.\a: */
if (this->path[n - 1] != '\\' &&
(strncmp (this->path, "\\\\.\\", 4) != 0))
{
this->modifiable_path ()[n] = '\\';
this->modifiable_path ()[n + 1] = '\0';
}
}
}
if (saw_symlinks)
set_has_symlinks ();
if (opt & PC_OPEN)
path_flags |= PATH_OPEN;
if (opt & PC_CTTY)
path_flags |= PATH_CTTY;
if (opt & PC_POSIX)
{
if (tail < path_end && tail > path_copy + 1)
*tail = '/';
set_posix (path_copy);
if (is_msdos && dos_file_warning && !(opt & PC_NOWARN))
warn_msdos (src);
}
#if 0
if (!error)
{
last_path_conv = *this;
strcpy (last_src, src);
}
#endif
}
__except (NO_ERROR)
{
error = EFAULT;
}
__endtry
}
path_conv::~path_conv ()
{
if (posix_path)
{
cfree ((void *) posix_path);
posix_path = NULL;
}
if (path)
{
cfree (modifiable_path ());
path = NULL;
}
if (wide_path)
{
cfree (wide_path);
wide_path = NULL;
}
close_conv_handle ();
}
bool
path_conv::is_binary ()
{
tmp_pathbuf tp;
PWCHAR bintest = tp.w_get ();
DWORD bin;
return GetBinaryTypeW (get_wide_win32_path (bintest), &bin)
&& (bin == SCS_32BIT_BINARY || bin == SCS_64BIT_BINARY);
}
/* Helper function to fill the fai datastructure for a file. */
NTSTATUS
file_get_fai (HANDLE h, PFILE_ALL_INFORMATION pfai)
{
NTSTATUS status;
IO_STATUS_BLOCK io;
/* Some FSes (Netapps) don't implement FileNetworkOpenInformation. */
status = NtQueryInformationFile (h, &io, pfai, sizeof *pfai,
FileAllInformation);
if (status == STATUS_BUFFER_OVERFLOW)
status = STATUS_SUCCESS;
return status;
}
/* Normalize a Win32 path.
/'s are converted to \'s in the process.
All duplicate \'s, except for 2 leading \'s, are deleted.
The result is 0 for success, or an errno error value.
FIXME: A lot of this should be mergeable with the POSIX critter. */
int
normalize_win32_path (const char *src, char *dst, char *&tail)
{
const char *src_start = src;
bool beg_src_slash = isdirsep (src[0]);
tail = dst;
/* Skip long path name prefixes in Win32 or NT syntax. */
if (beg_src_slash && (src[1] == '?' || isdirsep (src[1]))
&& src[2] == '?' && isdirsep (src[3]))
{
src += 4;
if (src[1] != ':') /* native UNC path */
src += 2; /* Fortunately the first char is not copied... */
else
beg_src_slash = false;
}
if (beg_src_slash && isdirsep (src[1]))
{
if (isdirsep (src[2]))
{
/* More than two slashes are just folded into one. */
src += 2;
while (isdirsep (src[1]))
++src;
}
else
{
/* Two slashes start a network or device path. */
*tail++ = '\\';
src++;
if (src[1] == '.' && isdirsep (src[2]))
{
*tail++ = '\\';
*tail++ = '.';
src += 2;
}
}
}
if (tail == dst)
{
if (isdrive (src))
/* Always convert drive letter to uppercase for case sensitivity. */
*tail++ = cyg_toupper (*src++);
else if (*src != '/')
{
if (beg_src_slash)
tail += cygheap->cwd.get_drive (dst);
else if (!cygheap->cwd.get (dst, 0))
return get_errno ();
else
{
tail = strchr (tail, '\0');
if (tail[-1] != '\\')
*tail++ = '\\';
}
}
}
while (*src)
{
/* Strip duplicate /'s. */
if (isdirsep (src[0]) && isdirsep (src[1]))
src++;
/* Ignore "./". */
else if (src[0] == '.' && isdirsep (src[1])
&& (src == src_start || isdirsep (src[-1])))
src += 2;
/* Backup if "..". */
else if (src[0] == '.' && src[1] == '.'
/* dst must be greater than dst_start */
&& tail[-1] == '\\')
{
if (!isdirsep (src[2]) && src[2] != '\0')
*tail++ = *src++;
else
{
/* Back up over /, but not if it's the first one. */
if (tail > dst + 1)
tail--;
/* Now back up to the next /. */
while (tail > dst + 1 && tail[-1] != '\\' && tail[-2] != ':')
tail--;
src += 2;
/* Skip /'s to the next path component. */
while (isdirsep (*src))
src++;
}
}
/* Otherwise, add char to result. */
else
{
if (*src == '/')
*tail++ = '\\';
else
*tail++ = *src;
src++;
}
if ((tail - dst) >= NT_MAX_PATH)
return ENAMETOOLONG;
}
if (tail > dst + 1 && tail[-1] == '.' && tail[-2] == '\\')
tail--;
*tail = '\0';
debug_printf ("%s = normalize_win32_path (%s)", dst, src_start);
return 0;
}
/* Various utilities. */
/* nofinalslash: Remove trailing / and \ from SRC (except for the
first one). It is ok for src == dst. */
void __reg2
nofinalslash (const char *src, char *dst)
{
int len = strlen (src);
if (src != dst)
memcpy (dst, src, len + 1);
while (len > 1 && isdirsep (dst[--len]))
dst[len] = '\0';
}
/* conv_path_list: Convert a list of path names to/from Win32/POSIX. */
static int
conv_path_list (const char *src, char *dst, size_t size,
cygwin_conv_path_t what)
{
tmp_pathbuf tp;
char src_delim, dst_delim;
size_t len;
bool env_cvt = false;
if (what == (cygwin_conv_path_t) ENV_CVT)
{
what = CCP_WIN_A_TO_POSIX | CCP_RELATIVE;
env_cvt = true;
}
if ((what & CCP_CONVTYPE_MASK) == CCP_WIN_A_TO_POSIX)
{
src_delim = ';';
dst_delim = ':';
}
else
{
src_delim = ':';
dst_delim = ';';
}
char *srcbuf;
len = strlen (src) + 1;
if (len <= NT_MAX_PATH * sizeof (WCHAR))
srcbuf = (char *) tp.w_get ();
else
srcbuf = (char *) alloca (len);
int err = 0;
char *d = dst - 1;
bool saw_empty = false;
do
{
char *srcpath = srcbuf;
char *s = strccpy (srcpath, &src, src_delim);
size_t len = s - srcpath;
if (len >= NT_MAX_PATH)
{
err = ENAMETOOLONG;
break;
}
/* Paths in Win32 path lists in the environment (%Path%), are often
enclosed in quotes (usually paths with spaces). Trailing backslashes
are common, too. Remove them. */
if (env_cvt && len)
{
if (*srcpath == '"')
{
++srcpath;
*--s = '\0';
len -= 2;
}
while (len && s[-1] == '\\')
{
*--s = '\0';
--len;
}
}
if (len)
{
++d;
err = cygwin_conv_path (what, srcpath, d, size - (d - dst));
}
else if ((what & CCP_CONVTYPE_MASK) == CCP_POSIX_TO_WIN_A)
{
++d;
err = cygwin_conv_path (what, ".", d, size - (d - dst));
}
else
{
if (env_cvt)
saw_empty = true;
continue;
}
if (err)
break;
d = strchr (d, '\0');
*d = dst_delim;
}
while (*src++);
if (saw_empty)
err = EIDRM;
if (d < dst)
d++;
*d = '\0';
return err;
}
/********************** Symbolic Link Support **************************/
/* Create a symlink from FROMPATH to TOPATH. */
extern "C" int
symlink (const char *oldpath, const char *newpath)
{
return symlink_worker (oldpath, newpath, false);
}
static int
symlink_nfs (const char *oldpath, path_conv &win32_newpath)
{
/* On NFS, create symlinks by calling NtCreateFile with an EA of type
NfsSymlinkTargetName containing ... the symlink target name. */
tmp_pathbuf tp;
PFILE_FULL_EA_INFORMATION pffei;
NTSTATUS status;
HANDLE fh;
OBJECT_ATTRIBUTES attr;
IO_STATUS_BLOCK io;
pffei = (PFILE_FULL_EA_INFORMATION) tp.w_get ();
pffei->NextEntryOffset = 0;
pffei->Flags = 0;
pffei->EaNameLength = sizeof (NFS_SYML_TARGET) - 1;
char *EaValue = stpcpy (pffei->EaName, NFS_SYML_TARGET) + 1;
pffei->EaValueLength = sizeof (WCHAR) *
(sys_mbstowcs ((PWCHAR) EaValue, NT_MAX_PATH, oldpath) - 1);
status = NtCreateFile (&fh, FILE_WRITE_DATA | FILE_WRITE_EA | SYNCHRONIZE,
win32_newpath.get_object_attr (attr, sec_none_nih),
&io, NULL, FILE_ATTRIBUTE_SYSTEM,
FILE_SHARE_VALID_FLAGS, FILE_CREATE,
FILE_SYNCHRONOUS_IO_NONALERT
| FILE_OPEN_FOR_BACKUP_INTENT,
pffei, NT_MAX_PATH * sizeof (WCHAR));
if (!NT_SUCCESS (status))
{
__seterrno_from_nt_status (status);
return -1;
}
NtClose (fh);
return 0;
}
/* Count backslashes between s and e. */
static inline int
cnt_bs (PWCHAR s, PWCHAR e)
{
int num = 0;
while (s < e)
if (*s++ == L'\\')
++num;
return num;
}
static int
symlink_native (const char *oldpath, path_conv &win32_newpath)
{
tmp_pathbuf tp;
path_conv win32_oldpath;
PUNICODE_STRING final_oldpath, final_newpath;
UNICODE_STRING final_oldpath_buf;
if (isabspath (oldpath))
{
win32_oldpath.check (oldpath, PC_SYM_NOFOLLOW, stat_suffixes);
final_oldpath = win32_oldpath.get_nt_native_path ();
}
else
{
/* The symlink target is relative to the directory in which
the symlink gets created, not relative to the cwd. Therefore
we have to mangle the path quite a bit before calling path_conv. */
ssize_t len = strrchr (win32_newpath.get_posix (), '/')
- win32_newpath.get_posix () + 1;
char *absoldpath = tp.t_get ();
stpcpy (stpncpy (absoldpath, win32_newpath.get_posix (), len),
oldpath);
win32_oldpath.check (absoldpath, PC_SYM_NOFOLLOW, stat_suffixes);
/* Try hard to keep Windows symlink path relative. */
/* 1. Find common path prefix. Skip leading \\?\, but take pre-increment
of the following loop into account. */
PWCHAR c_old = win32_oldpath.get_nt_native_path ()->Buffer + 3;
PWCHAR c_new = win32_newpath.get_nt_native_path ()->Buffer + 3;
/* Windows compatible == always check case insensitive. */
while (towupper (*++c_old) == towupper (*++c_new))
;
/* The last component could share a common prefix, so make sure we end
up on the first char after the last common backslash. */
while (c_old[-1] != L'\\')
--c_old, --c_new;
/* 2. Check if prefix is long enough. The prefix must at least points to
a complete device: \\?\X:\ or \\?\UNC\server\share\ are the minimum
prefix strings. We start counting behind the \\?\ for speed. */
int num = cnt_bs (win32_oldpath.get_nt_native_path ()->Buffer + 4, c_old);
if (num < 1 /* locale drive. */
|| (win32_oldpath.get_nt_native_path ()->Buffer[5] != L':'
&& num < 3)) /* UNC path. */
{
/* 3a. No valid common path prefix: Create absolute symlink. */
final_oldpath = win32_oldpath.get_nt_native_path ();
}
else
{
/* 3b. Common path prefx. Count number of additional directories
in symlink's path, and prepend as much ".." path components
to the target path. */
PWCHAR e_new = win32_newpath.get_nt_native_path ()->Buffer
+ win32_newpath.get_nt_native_path ()->Length
/ sizeof (WCHAR);
num = cnt_bs (c_new, e_new);
final_oldpath = &final_oldpath_buf;
final_oldpath->Buffer = tp.w_get ();
PWCHAR e_old = final_oldpath->Buffer;
while (num-- > 0)
e_old = wcpcpy (e_old, L"..\\");
wcpcpy (e_old, c_old);
}
}
/* If the symlink target doesn't exist, don't create native symlink.
Otherwise the directory flag in the symlink is potentially wrong
when the target comes into existence, and native tools will fail.
This is so screwball. This is no problem on AFS, fortunately. */
if (!win32_oldpath.exists () && !win32_oldpath.fs_is_afs ())
{
SetLastError (ERROR_FILE_NOT_FOUND);
return -1;
}
/* Don't allow native symlinks to Cygwin special files. However, the
caller shoud know because this case shouldn't be covered by the
default "nativestrict" behaviour, so we use a special return code. */
if (win32_oldpath.isspecial ())
return -2;
/* Convert native paths to Win32 UNC paths. */
final_newpath = win32_newpath.get_nt_native_path ();
final_newpath->Buffer[1] = L'\\';
/* oldpath may be relative. Make sure to convert only absolute paths
to Win32 paths. */
if (final_oldpath->Buffer[0] == L'\\')
{
/* Workaround Windows 8.1 bug. On Windows 8.1, the ShellExecuteW
function does not handle the long path prefix correctly for symlink
targets. Thus, we create simple short paths < MAX_PATH without
long path prefix. */
if (RtlEqualUnicodePathPrefix (final_oldpath, &ro_u_uncp, TRUE)
&& final_oldpath->Length < (MAX_PATH + 6) * sizeof (WCHAR))
{
final_oldpath->Buffer += 6;
final_oldpath->Buffer[0] = L'\\';
}
else if (final_oldpath->Length < (MAX_PATH + 4) * sizeof (WCHAR))
final_oldpath->Buffer += 4;
else /* Stick to long path, fix native prefix for Win32 API calls. */
final_oldpath->Buffer[1] = L'\\';
}
/* Try to create native symlink. */
if (!CreateSymbolicLinkW (final_newpath->Buffer, final_oldpath->Buffer,
win32_oldpath.isdir ()
? SYMBOLIC_LINK_FLAG_DIRECTORY : 0))
{
/* Repair native newpath, we still need it. */
final_newpath->Buffer[1] = L'?';
return -1;
}
return 0;
}
int
symlink_worker (const char *oldpath, const char *newpath, bool isdevice)
{
int res = -1;
size_t len;
path_conv win32_newpath;
char *buf, *cp;
tmp_pathbuf tp;
unsigned check_opt;
bool has_trailing_dirsep = false;
winsym_t wsym_type;
/* POSIX says that empty 'newpath' is invalid input while empty
'oldpath' is valid -- it's symlink resolver job to verify if
symlink contents point to existing filesystem object */
__try
{
if (!*oldpath || !*newpath)
{
set_errno (ENOENT);
__leave;
}
if (strlen (oldpath) > SYMLINK_MAX)
{
set_errno (ENAMETOOLONG);
__leave;
}
/* Trailing dirsep is a no-no. */
len = strlen (newpath);
has_trailing_dirsep = isdirsep (newpath[len - 1]);
if (has_trailing_dirsep)
{
newpath = strdup (newpath);
((char *) newpath)[len - 1] = '\0';
}
check_opt = PC_SYM_NOFOLLOW | PC_POSIX | (isdevice ? PC_NOWARN : 0);
/* We need the normalized full path below. */
win32_newpath.check (newpath, check_opt, stat_suffixes);
/* Default symlink type is determined by global allow_winsymlinks
variable. Device files are always shortcuts. */
wsym_type = isdevice ? WSYM_lnk : allow_winsymlinks;
/* NFS has its own, dedicated way to create symlinks. */
if (win32_newpath.fs_is_nfs ())
wsym_type = WSYM_nfs;
/* MVFS doesn't handle the SYSTEM DOS attribute, but it handles the R/O
attribute. Therefore we create symlinks on MVFS always as shortcuts. */
else if (win32_newpath.fs_is_mvfs ())
wsym_type = WSYM_lnk;
/* AFS only supports native symlinks. */
else if (win32_newpath.fs_is_afs ())
{
/* Bail out if OS doesn't support native symlinks. */
if (wincap.max_sys_priv () < SE_CREATE_SYMBOLIC_LINK_PRIVILEGE)
{
set_errno (EPERM);
__leave;
}
wsym_type = WSYM_nativestrict;
}
/* Don't try native symlinks on FSes not supporting reparse points. */
else if ((wsym_type == WSYM_native || wsym_type == WSYM_nativestrict)
&& !(win32_newpath.fs_flags () & FILE_SUPPORTS_REPARSE_POINTS))
wsym_type = WSYM_sysfile;
/* Attach .lnk suffix when shortcut is requested. */
if (wsym_type == WSYM_lnk && !win32_newpath.exists ()
&& (isdevice || !win32_newpath.fs_is_nfs ()))
{
char *newplnk = tp.c_get ();
stpcpy (stpcpy (newplnk, newpath), ".lnk");
win32_newpath.check (newplnk, check_opt);
}
if (win32_newpath.error)
{
set_errno (win32_newpath.error);
__leave;
}
syscall_printf ("symlink (%s, %S) wsym_type %d", oldpath,
win32_newpath.get_nt_native_path (), wsym_type);
if ((!isdevice && win32_newpath.exists ())
|| win32_newpath.is_auto_device ())
{
set_errno (EEXIST);
__leave;
}
if (has_trailing_dirsep && !win32_newpath.exists ())
{
set_errno (ENOENT);
__leave;
}
/* Handle NFS and native symlinks in their own functions. */
switch (wsym_type)
{
case WSYM_nfs:
res = symlink_nfs (oldpath, win32_newpath);
__leave;
case WSYM_native:
case WSYM_nativestrict:
res = symlink_native (oldpath, win32_newpath);
if (!res)
__leave;
/* Strictly native? Too bad, unless the target is a Cygwin
special file. */
if (res == -1 && wsym_type == WSYM_nativestrict)
{
__seterrno ();
__leave;
}
/* Otherwise, fall back to default symlink type. */
wsym_type = WSYM_sysfile;
break;
default:
break;
}
if (wsym_type == WSYM_lnk)
{
path_conv win32_oldpath;
ITEMIDLIST *pidl = NULL;
size_t full_len = 0;
unsigned short oldpath_len, desc_len, relpath_len, pidl_len = 0;
char desc[MAX_PATH + 1], *relpath;
if (!isdevice)
{
/* First create an IDLIST to learn how big our shortcut is
going to be. */
IShellFolder *psl;
/* The symlink target is relative to the directory in which the
symlink gets created, not relative to the cwd. Therefore we
have to mangle the path quite a bit before calling path_conv.*/
if (isabspath (oldpath))
win32_oldpath.check (oldpath,
PC_SYM_NOFOLLOW,
stat_suffixes);
else
{
len = strrchr (win32_newpath.get_posix (), '/')
- win32_newpath.get_posix () + 1;
char *absoldpath = tp.t_get ();
stpcpy (stpncpy (absoldpath, win32_newpath.get_posix (),
len),
oldpath);
win32_oldpath.check (absoldpath, PC_SYM_NOFOLLOW,
stat_suffixes);
}
if (SUCCEEDED (SHGetDesktopFolder (&psl)))
{
WCHAR wc_path[win32_oldpath.get_wide_win32_path_len () + 1];
win32_oldpath.get_wide_win32_path (wc_path);
/* Amazing but true: Even though the ParseDisplayName method
takes a wide char path name, it does not understand the
Win32 prefix for long pathnames! So we have to tack off
the prefix and convert the path to the "normal" syntax
for ParseDisplayName. */
WCHAR *wc = wc_path + 4;
if (wc[1] != L':') /* native UNC path */
*(wc += 2) = L'\\';
HRESULT res;
if (SUCCEEDED (res = psl->ParseDisplayName (NULL, NULL, wc,
NULL, &pidl,
NULL)))
{
ITEMIDLIST *p;
for (p = pidl; p->mkid.cb > 0;
p = (ITEMIDLIST *)((char *) p + p->mkid.cb))
;
pidl_len = (char *) p - (char *) pidl + 2;
}
psl->Release ();
}
}
/* Compute size of shortcut file. */
full_len = sizeof (win_shortcut_hdr);
if (pidl_len)
full_len += sizeof (unsigned short) + pidl_len;
oldpath_len = strlen (oldpath);
/* Unfortunately the length of the description is restricted to a
length of 2000 bytes. We don't want to add considerations for
the different lengths and even 2000 bytes is not enough for long
path names. So what we do here is to set the description to the
POSIX path only if the path is not longer than MAX_PATH characters.
We append the full path name after the regular shortcut data
(see below), which works fine with Windows Explorer as well
as older Cygwin versions (as long as the whole file isn't bigger
than 8K). The description field is only used for backward
compatibility to older Cygwin versions and those versions are
not capable of handling long path names anyway. */
desc_len = stpcpy (desc, oldpath_len > MAX_PATH
? "[path too long]" : oldpath) - desc;
full_len += sizeof (unsigned short) + desc_len;
/* Devices get the oldpath string unchanged as relative path. */
if (isdevice)
{
relpath_len = oldpath_len;
stpcpy (relpath = tp.c_get (), oldpath);
}
else
{
relpath_len = strlen (win32_oldpath.get_win32 ());
stpcpy (relpath = tp.c_get (), win32_oldpath.get_win32 ());
}
full_len += sizeof (unsigned short) + relpath_len;
full_len += sizeof (unsigned short) + oldpath_len;
/* 1 byte more for trailing 0 written by stpcpy. */
if (full_len < NT_MAX_PATH * sizeof (WCHAR))
buf = tp.t_get ();
else
buf = (char *) alloca (full_len + 1);
/* Create shortcut header */
win_shortcut_hdr *shortcut_header = (win_shortcut_hdr *) buf;
memset (shortcut_header, 0, sizeof *shortcut_header);
shortcut_header->size = sizeof *shortcut_header;
shortcut_header->magic = GUID_shortcut;
shortcut_header->flags = (WSH_FLAG_DESC | WSH_FLAG_RELPATH);
if (pidl)
shortcut_header->flags |= WSH_FLAG_IDLIST;
shortcut_header->run = SW_NORMAL;
cp = buf + sizeof (win_shortcut_hdr);
/* Create IDLIST */
if (pidl)
{
*(unsigned short *)cp = pidl_len;
memcpy (cp += 2, pidl, pidl_len);
cp += pidl_len;
CoTaskMemFree (pidl);
}
/* Create description */
*(unsigned short *)cp = desc_len;
cp = stpcpy (cp += 2, desc);
/* Create relpath */
*(unsigned short *)cp = relpath_len;
cp = stpcpy (cp += 2, relpath);
/* Append the POSIX path after the regular shortcut data for
the long path support. */
unsigned short *plen = (unsigned short *) cp;
cp += 2;
*(PWCHAR) cp = 0xfeff; /* BOM */
cp += 2;
*plen = sys_mbstowcs ((PWCHAR) cp, NT_MAX_PATH, oldpath)
* sizeof (WCHAR);
cp += *plen;
}
else
{
/* Default technique creating a symlink. */
buf = tp.t_get ();
cp = stpcpy (buf, SYMLINK_COOKIE);
*(PWCHAR) cp = 0xfeff; /* BOM */
cp += 2;
/* Note that the terminating nul is written. */
cp += sys_mbstowcs ((PWCHAR) cp, NT_MAX_PATH, oldpath)
* sizeof (WCHAR);
}
OBJECT_ATTRIBUTES attr;
IO_STATUS_BLOCK io;
NTSTATUS status;
ULONG access;
HANDLE fh;
access = DELETE | FILE_GENERIC_WRITE;
if (isdevice && win32_newpath.exists ())
{
status = NtOpenFile (&fh, FILE_WRITE_ATTRIBUTES,
win32_newpath.get_object_attr (attr,
sec_none_nih),
&io, 0, FILE_OPEN_FOR_BACKUP_INTENT);
if (!NT_SUCCESS (status))
{
__seterrno_from_nt_status (status);
__leave;
}
status = NtSetAttributesFile (fh, FILE_ATTRIBUTE_NORMAL);
NtClose (fh);
if (!NT_SUCCESS (status))
{
__seterrno_from_nt_status (status);
__leave;
}
}
else if (!isdevice && win32_newpath.has_acls ()
&& !win32_newpath.isremote ())
/* If the filesystem supports ACLs, we will overwrite the DACL after the
call to NtCreateFile. This requires a handle with READ_CONTROL and
WRITE_DAC access, otherwise get_file_sd and set_file_sd both have to
open the file again.
FIXME: On remote NTFS shares open sometimes fails because even the
creator of the file doesn't have the right to change the DACL.
I don't know what setting that is or how to recognize such a share,
so for now we don't request WRITE_DAC on remote drives. */
access |= READ_CONTROL | WRITE_DAC;
status = NtCreateFile (&fh, access,
win32_newpath.get_object_attr (attr, sec_none_nih),
&io, NULL, FILE_ATTRIBUTE_NORMAL,
FILE_SHARE_VALID_FLAGS,
isdevice ? FILE_OVERWRITE_IF : FILE_CREATE,
FILE_SYNCHRONOUS_IO_NONALERT
| FILE_NON_DIRECTORY_FILE
| FILE_OPEN_FOR_BACKUP_INTENT,
NULL, 0);
if (!NT_SUCCESS (status))
{
__seterrno_from_nt_status (status);
__leave;
}
if (io.Information == FILE_CREATED && win32_newpath.has_acls ())
set_created_file_access (fh, win32_newpath,
S_IFLNK | STD_RBITS | STD_WBITS);
status = NtWriteFile (fh, NULL, NULL, NULL, &io, buf, cp - buf,
NULL, NULL);
if (NT_SUCCESS (status) && io.Information == (ULONG) (cp - buf))
{
status = NtSetAttributesFile (fh, wsym_type == WSYM_lnk
? FILE_ATTRIBUTE_READONLY
: FILE_ATTRIBUTE_SYSTEM);
if (!NT_SUCCESS (status))
debug_printf ("Setting attributes failed, status = %y", status);
res = 0;
}
else
{
__seterrno_from_nt_status (status);
FILE_DISPOSITION_INFORMATION fdi = { TRUE };
status = NtSetInformationFile (fh, &io, &fdi, sizeof fdi,
FileDispositionInformation);
if (!NT_SUCCESS (status))
debug_printf ("Setting delete dispostion failed, status = %y",
status);
}
NtClose (fh);
}
__except (EFAULT) {}
__endtry
syscall_printf ("%d = symlink_worker(%s, %s, %d)",
res, oldpath, newpath, isdevice);
if (has_trailing_dirsep)
free ((void *) newpath);
return res;
}
static bool
cmp_shortcut_header (win_shortcut_hdr *file_header)
{
/* A Cygwin or U/Win shortcut only contains a description and a relpath.
Cygwin shortcuts also might contain an ITEMIDLIST. The run type is
always set to SW_NORMAL. */
return file_header->size == sizeof (win_shortcut_hdr)
&& !memcmp (&file_header->magic, &GUID_shortcut, sizeof GUID_shortcut)
&& (file_header->flags & ~WSH_FLAG_IDLIST)
== (WSH_FLAG_DESC | WSH_FLAG_RELPATH)
&& file_header->run == SW_NORMAL;
}
int
symlink_info::check_shortcut (HANDLE h)
{
tmp_pathbuf tp;
win_shortcut_hdr *file_header;
char *buf, *cp;
unsigned short len;
int res = 0;
NTSTATUS status;
IO_STATUS_BLOCK io;
FILE_STANDARD_INFORMATION fsi;
LARGE_INTEGER off = { QuadPart:0LL };
status = NtQueryInformationFile (h, &io, &fsi, sizeof fsi,
FileStandardInformation);
if (!NT_SUCCESS (status))
{
set_error (EIO);
return 0;
}
if (fsi.EndOfFile.QuadPart <= (LONGLONG) sizeof (win_shortcut_hdr)
|| fsi.EndOfFile.QuadPart > 4 * 65536)
return 0;
if (fsi.EndOfFile.LowPart < NT_MAX_PATH * sizeof (WCHAR))
buf = (char *) tp.w_get ();
else
buf = (char *) alloca (fsi.EndOfFile.LowPart + 1);
status = NtReadFile (h, NULL, NULL, NULL, &io, buf, fsi.EndOfFile.LowPart,
&off, NULL);
if (!NT_SUCCESS (status))
{
if (status != STATUS_END_OF_FILE)
set_error (EIO);
return 0;
}
file_header = (win_shortcut_hdr *) buf;
if (io.Information != fsi.EndOfFile.LowPart
|| !cmp_shortcut_header (file_header))
return 0;
cp = buf + sizeof (win_shortcut_hdr);
if (file_header->flags & WSH_FLAG_IDLIST) /* Skip ITEMIDLIST */
cp += *(unsigned short *) cp + 2;
if (!(len = *(unsigned short *) cp))
return 0;
cp += 2;
/* Check if this is a device file - these start with the sequence :\\ */
if (strncmp (cp, ":\\", 2) == 0)
res = strlen (strcpy (contents, cp)); /* Don't mess with device files */
else
{
/* Has appended full path? If so, use it instead of description. */
unsigned short relpath_len = *(unsigned short *) (cp + len);
if (cp + len + 2 + relpath_len < buf + fsi.EndOfFile.LowPart)
{
cp += len + 2 + relpath_len;
len = *(unsigned short *) cp;
cp += 2;
}
if (*(PWCHAR) cp == 0xfeff) /* BOM */
{
char *tmpbuf = tp.c_get ();
if (sys_wcstombs (tmpbuf, NT_MAX_PATH, (PWCHAR) (cp + 2))
> SYMLINK_MAX)
return 0;
res = posixify (tmpbuf);
}
else if (len > SYMLINK_MAX)
return 0;
else
{
cp[len] = '\0';
res = posixify (cp);
}
}
if (res) /* It's a symlink. */
pflags |= PATH_SYMLINK | PATH_LNK;
return res;
}
int
symlink_info::check_sysfile (HANDLE h)
{
tmp_pathbuf tp;
char cookie_buf[sizeof (SYMLINK_COOKIE) - 1];
char *srcbuf = tp.c_get ();
int res = 0;
NTSTATUS status;
IO_STATUS_BLOCK io;
bool interix_symlink = false;
LARGE_INTEGER off = { QuadPart:0LL };
status = NtReadFile (h, NULL, NULL, NULL, &io, cookie_buf,
sizeof (cookie_buf), &off, NULL);
if (!NT_SUCCESS (status))
{
debug_printf ("ReadFile1 failed %y", status);
if (status != STATUS_END_OF_FILE)
set_error (EIO);
return 0;
}
off.QuadPart = io.Information;
if (io.Information == sizeof (cookie_buf)
&& memcmp (cookie_buf, SYMLINK_COOKIE, sizeof (cookie_buf)) == 0)
{
/* It's a symlink. */
pflags |= PATH_SYMLINK;
}
else if (io.Information == sizeof (cookie_buf)
&& memcmp (cookie_buf, SOCKET_COOKIE, sizeof (cookie_buf)) == 0)
pflags |= PATH_SOCKET;
else if (io.Information >= sizeof (INTERIX_SYMLINK_COOKIE)
&& memcmp (cookie_buf, INTERIX_SYMLINK_COOKIE,
sizeof (INTERIX_SYMLINK_COOKIE) - 1) == 0)
{
/* It's an Interix symlink. */
pflags |= PATH_SYMLINK;
interix_symlink = true;
/* Interix symlink cookies are shorter than Cygwin symlink cookies, so
in case of an Interix symlink cooky we have read too far into the
file. Set file pointer back to the position right after the cookie. */
off.QuadPart = sizeof (INTERIX_SYMLINK_COOKIE) - 1;
}
if (pflags & PATH_SYMLINK)
{
status = NtReadFile (h, NULL, NULL, NULL, &io, srcbuf,
NT_MAX_PATH, &off, NULL);
if (!NT_SUCCESS (status))
{
debug_printf ("ReadFile2 failed");
if (status != STATUS_END_OF_FILE)
set_error (EIO);
}
else if (*(PWCHAR) srcbuf == 0xfeff /* BOM */
|| interix_symlink)
{
/* Add trailing 0 to Interix symlink target. Skip BOM in Cygwin
symlinks. */
if (interix_symlink)
((PWCHAR) srcbuf)[io.Information / sizeof (WCHAR)] = L'\0';
else
srcbuf += 2;
char *tmpbuf = tp.c_get ();
if (sys_wcstombs (tmpbuf, NT_MAX_PATH, (PWCHAR) srcbuf)
> SYMLINK_MAX)
debug_printf ("symlink string too long");
else
res = posixify (tmpbuf);
}
else if (io.Information > SYMLINK_MAX + 1)
debug_printf ("symlink string too long");
else
res = posixify (srcbuf);
}
return res;
}
int
symlink_info::check_reparse_point (HANDLE h, bool remote)
{
tmp_pathbuf tp;
NTSTATUS status;
IO_STATUS_BLOCK io;
PREPARSE_DATA_BUFFER rp = (PREPARSE_DATA_BUFFER) tp.c_get ();
UNICODE_STRING subst;
char srcbuf[SYMLINK_MAX + 7];
/* On remote drives or under heavy load, NtFsControlFile can return with
STATUS_PENDING. If so, instead of creating an event object, just set
io.Status to an invalid value and perform a minimal wait until io.Status
changed. */
memset (&io, 0xff, sizeof io);
status = NtFsControlFile (h, NULL, NULL, NULL, &io,
FSCTL_GET_REPARSE_POINT, NULL, 0, (LPVOID) rp,
MAXIMUM_REPARSE_DATA_BUFFER_SIZE);
if (status == STATUS_PENDING)
{
while (io.Status == (NTSTATUS) 0xffffffff)
Sleep (1L);
status = io.Status;
}
if (!NT_SUCCESS (status))
{
debug_printf ("NtFsControlFile(FSCTL_GET_REPARSE_POINT) failed, %y",
status);
/* When accessing the root dir of some remote drives (observed with
OS X shares), the FILE_ATTRIBUTE_REPARSE_POINT flag is set, but
the followup call to NtFsControlFile(FSCTL_GET_REPARSE_POINT)
returns with STATUS_NOT_A_REPARSE_POINT. That's quite buggy, but
we cope here with this scenario by not setting an error code. */
if (status != STATUS_NOT_A_REPARSE_POINT)
set_error (EIO);
return 0;
}
if (rp->ReparseTag == IO_REPARSE_TAG_SYMLINK)
/* Windows evaluates native symlink literally. If a remote symlink points
to, say, C:\foo, it will be handled as if the target is the local file
C:\foo. That comes in handy since that's how symlinks are treated under
POSIX as well. */
RtlInitCountedUnicodeString (&subst,
(WCHAR *)((char *)rp->SymbolicLinkReparseBuffer.PathBuffer
+ rp->SymbolicLinkReparseBuffer.SubstituteNameOffset),
rp->SymbolicLinkReparseBuffer.SubstituteNameLength);
else if (!remote && rp->ReparseTag == IO_REPARSE_TAG_MOUNT_POINT)
{
/* Don't handle junctions on remote filesystems as symlinks. This type
of reparse point is handled transparently by the OS so that the
target of the junction is the remote directory it is supposed to
point to. If we handle it as symlink, it will be mistreated as
pointing to a dir on the local system. */
RtlInitCountedUnicodeString (&subst,
(WCHAR *)((char *)rp->MountPointReparseBuffer.PathBuffer
+ rp->MountPointReparseBuffer.SubstituteNameOffset),
rp->MountPointReparseBuffer.SubstituteNameLength);
if (RtlEqualUnicodePathPrefix (&subst, &ro_u_volume, TRUE))
{
/* Volume mount point. Not treated as symlink. The return
value of -1 is a hint for the caller to treat this as a
volume mount point. */
return -1;
}
}
else
{
/* Maybe it's a reparse point, but it's certainly not one we recognize.
Drop REPARSE attribute so we don't try to use the flag accidentally.
It's just some arbitrary file or directory for us. */
fileattr &= ~FILE_ATTRIBUTE_REPARSE_POINT;
return 0;
}
sys_wcstombs (srcbuf, SYMLINK_MAX + 7, subst.Buffer,
subst.Length / sizeof (WCHAR));
pflags |= PATH_SYMLINK | PATH_REP;
/* A symlink is never a directory. */
fileattr &= ~FILE_ATTRIBUTE_DIRECTORY;
return posixify (srcbuf);
}
int
symlink_info::check_nfs_symlink (HANDLE h)
{
tmp_pathbuf tp;
NTSTATUS status;
IO_STATUS_BLOCK io;
struct {
FILE_GET_EA_INFORMATION fgei;
char buf[sizeof (NFS_SYML_TARGET)];
} fgei_buf;
PFILE_FULL_EA_INFORMATION pffei;
int res = 0;
/* To find out if the file is a symlink and to get the symlink target,
try to fetch the NfsSymlinkTargetName EA. */
fgei_buf.fgei.NextEntryOffset = 0;
fgei_buf.fgei.EaNameLength = sizeof (NFS_SYML_TARGET) - 1;
stpcpy (fgei_buf.fgei.EaName, NFS_SYML_TARGET);
pffei = (PFILE_FULL_EA_INFORMATION) tp.w_get ();
status = NtQueryEaFile (h, &io, pffei, NT_MAX_PATH * sizeof (WCHAR), TRUE,
&fgei_buf.fgei, sizeof fgei_buf, NULL, TRUE);
if (NT_SUCCESS (status) && pffei->EaValueLength > 0)
{
PWCHAR spath = (PWCHAR)
(pffei->EaName + pffei->EaNameLength + 1);
res = sys_wcstombs (contents, SYMLINK_MAX + 1,
spath, pffei->EaValueLength);
pflags |= PATH_SYMLINK;
}
return res;
}
int
symlink_info::posixify (char *srcbuf)
{
/* The definition for a path in a native symlink is a bit weird. The Flags
value seem to contain 0 for absolute paths (stored as NT native path)
and 1 for relative paths. Relative paths are paths not starting with a
drive letter. These are not converted to NT native, but stored as
given. A path starting with a single backslash is relative to the
current drive thus a "relative" value (Flags == 1).
Funny enough it's possible to store paths with slashes instead of
backslashes, but they are evaluated incorrectly by subsequent Windows
calls like CreateFile (ERROR_INVALID_NAME). So, what we do here is to
take paths starting with slashes at face value, evaluating them as
Cygwin specific POSIX paths.
A path starting with two slashes(!) or backslashes is converted into an
NT UNC path. Unfortunately, in contrast to POSIX rules, paths starting
with three or more (back)slashes are also converted into UNC paths,
just incorrectly sticking to one redundant leading backslash. We go
along with this behaviour to avoid scenarios in which native tools access
other files than Cygwin.
The above rules are used exactly the same way on Cygwin specific symlinks
(sysfiles and shortcuts) to eliminate non-POSIX paths in the output. */
/* Eliminate native NT prefixes. */
if (srcbuf[0] == '\\' && !strncmp (srcbuf + 1, "??\\", 3))
{
srcbuf += 4;
if (srcbuf[1] != ':') /* native UNC path */
*(srcbuf += 2) = '\\';
}
if (isdrive (srcbuf))
mount_table->conv_to_posix_path (srcbuf, contents, 0);
else if (srcbuf[0] == '\\')
{
if (srcbuf[1] == '\\') /* UNC path */
slashify (srcbuf, contents, 0);
else /* Paths starting with \ are current drive relative. */
{
char cvtbuf[SYMLINK_MAX + 1];
stpcpy (cvtbuf + cygheap->cwd.get_drive (cvtbuf), srcbuf);
mount_table->conv_to_posix_path (cvtbuf, contents, 0);
}
}
else /* Everything else is taken as is. */
slashify (srcbuf, contents, 0);
return strlen (contents);
}
enum
{
SCAN_BEG,
SCAN_LNK,
SCAN_HASLNK,
SCAN_JUSTCHECK,
SCAN_JUSTCHECKTHIS, /* Never try to append a suffix. */
SCAN_APPENDLNK,
SCAN_EXTRALNK,
SCAN_DONE,
};
class suffix_scan
{
const suffix_info *suffixes, *suffixes_start;
int nextstate;
char *eopath;
size_t namelen;
public:
const char *path;
char *has (const char *, const suffix_info *);
int next ();
int lnk_match () {return nextstate >= SCAN_APPENDLNK;}
size_t name_len () {return namelen;}
};
char *
suffix_scan::has (const char *in_path, const suffix_info *in_suffixes)
{
nextstate = SCAN_BEG;
suffixes = suffixes_start = in_suffixes;
const char *fname = strrchr (in_path, '\\');
fname = fname ? fname + 1 : in_path;
char *ext_here = strrchr (fname, '.');
path = in_path;
eopath = strchr (path, '\0');
if (!ext_here)
goto noext;
if (suffixes)
{
/* Check if the extension matches a known extension */
for (const suffix_info *ex = in_suffixes; ex->name != NULL; ex++)
if (ascii_strcasematch (ext_here, ex->name))
{
nextstate = SCAN_JUSTCHECK;
suffixes = NULL; /* Has an extension so don't scan for one. */
goto done;
}
}
/* Didn't match. Use last resort -- .lnk. */
if (ascii_strcasematch (ext_here, ".lnk"))
{
nextstate = SCAN_HASLNK;
suffixes = NULL;
}
noext:
ext_here = eopath;
done:
namelen = eopath - fname;
/* Avoid attaching suffixes if the resulting filename would be invalid.
For performance reasons we don't check the length of a suffix, since
we know that all suffixes are 4 chars in length.
FIXME: This is not really correct. A fully functional test should
work on wide character paths. This would probably also speed
up symlink_info::check. */
if (namelen > NAME_MAX - 4)
{
nextstate = SCAN_JUSTCHECKTHIS;
suffixes = NULL;
}
return ext_here;
}
int
suffix_scan::next ()
{
for (;;)
{
if (!suffixes)
switch (nextstate)
{
case SCAN_BEG:
suffixes = suffixes_start;
if (!suffixes)
{
nextstate = SCAN_LNK;
return 1;
}
nextstate = SCAN_EXTRALNK;
/* fall through to suffix checking below */
break;
case SCAN_HASLNK:
nextstate = SCAN_APPENDLNK; /* Skip SCAN_BEG */
return 1;
case SCAN_EXTRALNK:
nextstate = SCAN_DONE;
*eopath = '\0';
return 0;
case SCAN_JUSTCHECK:
nextstate = SCAN_LNK;
return 1;
case SCAN_JUSTCHECKTHIS:
nextstate = SCAN_DONE;
return 1;
case SCAN_LNK:
case SCAN_APPENDLNK:
nextstate = SCAN_DONE;
if (namelen + (*eopath ? 8 : 4) > NAME_MAX)
{
*eopath = '\0';
return 0;
}
strcat (eopath, ".lnk");
return 1;
default:
*eopath = '\0';
return 0;
}
while (suffixes && suffixes->name)
if (nextstate == SCAN_EXTRALNK
&& (!suffixes->addon || namelen > NAME_MAX - 8))
suffixes++;
else
{
strcpy (eopath, suffixes->name);
if (nextstate == SCAN_EXTRALNK)
strcat (eopath, ".lnk");
suffixes++;
return 1;
}
suffixes = NULL;
}
}
bool
symlink_info::set_error (int in_errno)
{
bool res;
if (!(pflags & PATH_NO_ACCESS_CHECK) || in_errno == ENAMETOOLONG || in_errno == EIO)
{
error = in_errno;
res = true;
}
else if (in_errno == ENOENT)
res = true;
else
{
fileattr = FILE_ATTRIBUTE_NORMAL;
res = false;
}
return res;
}
bool
symlink_info::parse_device (const char *contents)
{
char *endptr;
_major_t mymajor;
_major_t myminor;
_mode_t mymode;
mymajor = strtol (contents += 2, &endptr, 16);
if (endptr == contents)
return isdevice = false;
contents = endptr;
myminor = strtol (++contents, &endptr, 16);
if (endptr == contents)
return isdevice = false;
contents = endptr;
mymode = strtol (++contents, &endptr, 16);
if (endptr == contents)
return isdevice = false;
if ((mymode & S_IFMT) == S_IFIFO)
{
mymajor = _major (FH_FIFO);
myminor = _minor (FH_FIFO);
}
major = mymajor;
minor = myminor;
mode = mymode;
return isdevice = true;
}
/* Check if PATH is a symlink. PATH must be a valid Win32 path name.
If PATH is a symlink, put the value of the symlink--the file to
which it points--into BUF. The value stored in BUF is not
necessarily null terminated. BUFLEN is the length of BUF; only up
to BUFLEN characters will be stored in BUF. BUF may be NULL, in
which case nothing will be stored.
Set *SYML if PATH is a symlink.
Set *EXEC if PATH appears to be executable. This is an efficiency
hack because we sometimes have to open the file anyhow. *EXEC will
not be set for every executable file.
Return -1 on error, 0 if PATH is not a symlink, or the length
stored into BUF if PATH is a symlink. */
int
symlink_info::check (char *path, const suffix_info *suffixes, fs_info &fs,
path_conv_handle &conv_hdl)
{
int res;
HANDLE h;
NTSTATUS status;
UNICODE_STRING upath;
OBJECT_ATTRIBUTES attr;
IO_STATUS_BLOCK io;
suffix_scan suffix;
const ULONG ci_flag = cygwin_shared->obcaseinsensitive
|| (pflags & PATH_NOPOSIX) ? OBJ_CASE_INSENSITIVE : 0;
/* TODO: Temporarily do all char->UNICODE conversion here. This should
already be slightly faster than using Ascii functions. */
tmp_pathbuf tp;
tp.u_get (&upath);
InitializeObjectAttributes (&attr, &upath, ci_flag, NULL, NULL);
/* This label is used in case we encounter a FS which only handles
DOS paths. See below. */
bool restarted = false;
restart:
h = NULL;
res = 0;
contents[0] = '\0';
issymlink = true;
isdevice = false;
major = 0;
minor = 0;
mode = 0;
pflags &= ~(PATH_SYMLINK | PATH_LNK | PATH_REP);
PVOID eabuf = &nfs_aol_ffei;
ULONG easize = sizeof nfs_aol_ffei;
ext_here = suffix.has (path, suffixes);
extn = ext_here - path;
bool had_ext = !!*ext_here;
/* If the filename is too long, don't even try. */
if (suffix.name_len () > NAME_MAX)
{
set_error (ENAMETOOLONG);
goto file_not_symlink;
}
while (suffix.next ())
{
error = 0;
get_nt_native_path (suffix.path, upath, pflags & PATH_DOS);
if (h)
{
NtClose (h);
h = NULL;
}
/* The EA given to NtCreateFile allows to get a handle to a symlink on
an NFS share, rather than getting a handle to the target of the
symlink (which would spoil the task of this method quite a bit).
Fortunately it's ignored on most other file systems so we don't have
to special case NFS too much. */
status = NtCreateFile (&h,
READ_CONTROL | FILE_READ_ATTRIBUTES | FILE_READ_EA,
&attr, &io, NULL, 0, FILE_SHARE_VALID_FLAGS,
FILE_OPEN,
FILE_OPEN_REPARSE_POINT
| FILE_OPEN_FOR_BACKUP_INTENT,
eabuf, easize);
debug_printf ("%y = NtCreateFile (%S)", status, &upath);
/* No right to access EAs or EAs not supported? */
if (!NT_SUCCESS (status)
&& (status == STATUS_ACCESS_DENIED
|| status == STATUS_EAS_NOT_SUPPORTED
|| status == STATUS_NOT_SUPPORTED
|| status == STATUS_INVALID_NETWORK_RESPONSE
/* Or a bug in Samba 3.2.x (x <= 7) when accessing a share's
root dir which has EAs enabled? */
|| status == STATUS_INVALID_PARAMETER))
{
/* If EAs are not supported, there's no sense to check them again
with suffixes attached. So we set eabuf/easize to 0 here once. */
if (status == STATUS_EAS_NOT_SUPPORTED
|| status == STATUS_NOT_SUPPORTED)
{
eabuf = NULL;
easize = 0;
}
status = NtOpenFile (&h, READ_CONTROL | FILE_READ_ATTRIBUTES,
&attr, &io, FILE_SHARE_VALID_FLAGS,
FILE_OPEN_REPARSE_POINT
| FILE_OPEN_FOR_BACKUP_INTENT);
debug_printf ("%y = NtOpenFile (no-EAs %S)", status, &upath);
}
if (status == STATUS_OBJECT_NAME_NOT_FOUND)
{
if (ci_flag == 0 && wincap.has_broken_udf ()
&& (!fs.inited () || fs.is_udf ()))
{
/* On NT 5.x UDF is broken (at least) in terms of case
sensitivity. When trying to open a file case sensitive,
the file appears to be non-existant. Another bug is
described in fs_info::update. */
attr.Attributes = OBJ_CASE_INSENSITIVE;
status = NtOpenFile (&h, READ_CONTROL | FILE_READ_ATTRIBUTES,
&attr, &io, FILE_SHARE_VALID_FLAGS,
FILE_OPEN_REPARSE_POINT
| FILE_OPEN_FOR_BACKUP_INTENT);
debug_printf ("%y = NtOpenFile (broken-UDF, %S)", status, &upath);
attr.Attributes = 0;
if (NT_SUCCESS (status))
{
if (!fs.inited ())
fs.update (&upath, h);
if (!fs.is_udf ())
{
NtClose (h);
h = NULL;
status = STATUS_OBJECT_NAME_NOT_FOUND;
}
}
}
/* There are filesystems out in the wild (Netapp, NWFS, and others)
which are uncapable of generating pathnames outside the Win32
rules. That means, filenames on these FSes must not have a
leading space or trailing dots and spaces. This code snippet
manages them. I really hope it's streamlined enough not to
slow down normal operation. This extra check only kicks in if
we encountered a STATUS_OBJECT_NAME_NOT_FOUND *and* we didn't
already attach a suffix *and* the above special case for UDF
on XP didn't succeeed. */
if (!restarted && !*ext_here && !(pflags & PATH_DOS) && !fs.inited ())
{
/* Check for trailing dot or space or leading space in
last component. */
char *p = ext_here - 1;
if (*p != '.' && *p != ' ')
{
while (*--p != '\\')
;
if (*++p != ' ')
p = NULL;
}
if (p)
{
/* If so, check if file resides on one of the known broken
FSes only supporting filenames following DOS rules. */
if (!fs.inited ())
fs.update (&upath, NULL);
if (fs.has_dos_filenames_only ())
{
/* If so, try again. Since we now know the FS, the
filenames will be tweaked to follow DOS rules via the
third parameter in the call to get_nt_native_path. */
pflags |= PATH_DOS;
restarted = true;
goto restart;
}
}
}
}
else if (status == STATUS_NETWORK_OPEN_RESTRICTION
|| status == STATUS_SYMLINK_CLASS_DISABLED)
{
/* These status codes are returned if you try to open a native
symlink and the usage of this kind of symlink is forbidden
(see fsutil). Since we can't open them at all, not even for
stat purposes, we have to return a POSIX error code which is
at least a bit helpful.
Additionally Windows 8 introduces a bug in NFS: If you have
a symlink to a directory, with symlinks underneath, resolving
the second level of symlinks fails if remote->remote symlinks
are disabled in fsutil. Unfortunately that's the default. */
set_error (ELOOP);
break;
}
if (NT_SUCCESS (status)
/* Check file system while we're having the file open anyway.
This speeds up path_conv noticably (~10%). */
&& (fs.inited () || fs.update (&upath, h)))
{
if (fs.is_nfs ())
{
status = nfs_fetch_fattr3 (h, conv_hdl.nfsattr ());
if (NT_SUCCESS (status))
fileattr = ((conv_hdl.nfsattr ()->type & 7) == NF3DIR)
? FILE_ATTRIBUTE_DIRECTORY : 0;
}
else
{
status = file_get_fai (h, conv_hdl.fai ());
if (NT_SUCCESS (status))
fileattr = conv_hdl.fai ()->BasicInformation.FileAttributes;
}
}
if (!NT_SUCCESS (status))
{
debug_printf ("%y = NtQueryInformationFile (%S)", status, &upath);
fileattr = INVALID_FILE_ATTRIBUTES;
/* One of the inner path components is invalid, or the path contains
invalid characters. Bail out with ENOENT.
Note that additional STATUS_OBJECT_PATH_INVALID and
STATUS_OBJECT_PATH_SYNTAX_BAD status codes exist. The first one
is seemingly not generated by NtQueryInformationFile, the latter
is only generated if the path is no absolute path within the
NT name space, which should not happen and would point to an
error in get_nt_native_path. Both status codes are deliberately
not tested here unless proved necessary. */
if (status == STATUS_OBJECT_PATH_NOT_FOUND
|| status == STATUS_OBJECT_NAME_INVALID
|| status == STATUS_BAD_NETWORK_PATH
|| status == STATUS_BAD_NETWORK_NAME
|| status == STATUS_NO_MEDIA_IN_DEVICE)
{
set_error (ENOENT);
goto file_not_symlink;
}
if (status != STATUS_OBJECT_NAME_NOT_FOUND
&& status != STATUS_NO_SUCH_FILE) /* ENOENT on NFS or 9x share */
{
/* The file exists, but the user can't access it for one reason
or the other. To get the file attributes we try to access the
information by opening the parent directory and getting the
file attributes using a matching NtQueryDirectoryFile call. */
UNICODE_STRING dirname, basename;
OBJECT_ATTRIBUTES dattr;
HANDLE dir;
struct {
FILE_ID_BOTH_DIR_INFORMATION fdi;
WCHAR dummy_buf[NAME_MAX + 1];
} fdi_buf;
RtlSplitUnicodePath (&upath, &dirname, &basename);
InitializeObjectAttributes (&dattr, &dirname, ci_flag,
NULL, NULL);
status = NtOpenFile (&dir, SYNCHRONIZE | FILE_LIST_DIRECTORY,
&dattr, &io, FILE_SHARE_VALID_FLAGS,
FILE_SYNCHRONOUS_IO_NONALERT
| FILE_OPEN_FOR_BACKUP_INTENT
| FILE_DIRECTORY_FILE);
if (!NT_SUCCESS (status))
{
debug_printf ("%y = NtOpenFile(%S)", status, &dirname);
/* There's a special case if the file is itself the root
of a drive which is not accessible by the current user.
This case is only recognized by the length of the
basename part. If it's 0, the incoming file is the
root of a drive. So we at least know it's a directory. */
if (basename.Length)
fileattr = FILE_ATTRIBUTE_DIRECTORY;
else
{
fileattr = 0;
set_error (geterrno_from_nt_status (status));
}
}
else
{
status = NtQueryDirectoryFile (dir, NULL, NULL, NULL, &io,
&fdi_buf, sizeof fdi_buf,
FileIdBothDirectoryInformation,
TRUE, &basename, TRUE);
/* Take the opportunity to check file system while we're
having the handle to the parent dir. */
fs.update (&upath, dir);
NtClose (dir);
if (!NT_SUCCESS (status))
{
debug_printf ("%y = NtQueryDirectoryFile(%S)",
status, &dirname);
if (status == STATUS_NO_SUCH_FILE)
{
/* This can happen when trying to access files
which match DOS device names on SMB shares.
NtOpenFile failed with STATUS_ACCESS_DENIED,
but the NtQueryDirectoryFile tells us the
file doesn't exist. We're suspicious in this
case and retry with the next suffix instead of
just giving up. */
set_error (ENOENT);
continue;
}
fileattr = 0;
}
else
{
PFILE_ALL_INFORMATION pfai = conv_hdl.fai ();
fileattr = fdi_buf.fdi.FileAttributes;
memcpy (&pfai->BasicInformation.CreationTime,
&fdi_buf.fdi.CreationTime,
4 * sizeof (LARGE_INTEGER));
pfai->BasicInformation.FileAttributes = fileattr;
pfai->StandardInformation.AllocationSize.QuadPart
= fdi_buf.fdi.AllocationSize.QuadPart;
pfai->StandardInformation.EndOfFile.QuadPart
= fdi_buf.fdi.EndOfFile.QuadPart;
pfai->StandardInformation.NumberOfLinks = 1;
pfai->InternalInformation.IndexNumber.QuadPart
= fdi_buf.fdi.FileId.QuadPart;
}
}
ext_tacked_on = !!*ext_here;
goto file_not_symlink;
}
set_error (ENOENT);
continue;
}
ext_tacked_on = !!*ext_here;
/* Don't allow to returns directories with appended suffix. If we found
a directory with a suffix which has been appended here, then this
directory doesn't match the request. So, just do as usual if file
hasn't been found. */
if (ext_tacked_on && !had_ext && (fileattr & FILE_ATTRIBUTE_DIRECTORY))
{
set_error (ENOENT);
continue;
}
res = -1;
/* Reparse points are potentially symlinks. This check must be
performed before checking the SYSTEM attribute for sysfile
symlinks, since reparse points can have this flag set, too.
For instance, Vista starts to create a couple of reparse points
with SYSTEM and HIDDEN flags set. */
if ((fileattr & FILE_ATTRIBUTE_REPARSE_POINT))
{
res = check_reparse_point (h, fs.is_remote_drive ());
if (res > 0)
{
/* A symlink is never a directory. */
conv_hdl.fai ()->BasicInformation.FileAttributes
&= ~FILE_ATTRIBUTE_DIRECTORY;
break;
}
else
{
/* Volume moint point or unrecognized reparse point type.
Make sure the open handle is not used in later stat calls.
The handle has been opened with the FILE_OPEN_REPARSE_POINT
flag, so it's a handle to the reparse point, not a handle
to the volumes root dir. */
pflags &= ~PC_KEEP_HANDLE;
/* Volume mount point: The filesystem information for the top
level directory should be for the volume top level directory,
rather than for the reparse point itself. So we fetch the
filesystem information again, but with a NULL handle.
This does what we want because fs_info::update opens the
handle without FILE_OPEN_REPARSE_POINT. */
if (res == -1)
fs.update (&upath, NULL);
}
}
/* Windows shortcuts are potentially treated as symlinks. Valid Cygwin
& U/WIN shortcuts are R/O, but definitely not directories. */
else if ((fileattr & (FILE_ATTRIBUTE_READONLY | FILE_ATTRIBUTE_DIRECTORY))
== FILE_ATTRIBUTE_READONLY && suffix.lnk_match ())
{
HANDLE sym_h;
status = NtOpenFile (&sym_h, SYNCHRONIZE | GENERIC_READ, &attr, &io,
FILE_SHARE_VALID_FLAGS,
FILE_OPEN_FOR_BACKUP_INTENT
| FILE_SYNCHRONOUS_IO_NONALERT);
if (!NT_SUCCESS (status))
res = 0;
else
{
res = check_shortcut (sym_h);
NtClose (sym_h);
}
if (!res)
{
/* If searching for `foo' and then finding a `foo.lnk' which
is no shortcut, return the same as if file not found. */
if (ext_tacked_on)
{
fileattr = INVALID_FILE_ATTRIBUTES;
set_error (ENOENT);
continue;
}
}
else if (contents[0] != ':' || contents[1] != '\\'
|| !parse_device (contents))
break;
}
/* If searching for `foo' and then finding a `foo.lnk' which is
no shortcut, return the same as if file not found. */
else if (suffix.lnk_match () && ext_tacked_on)
{
fileattr = INVALID_FILE_ATTRIBUTES;
set_error (ENOENT);
continue;
}
/* This is the old Cygwin method creating symlinks. A symlink will
have the `system' file attribute. Only files can be symlinks
(which can be symlinks to directories). */
else if ((fileattr & (FILE_ATTRIBUTE_SYSTEM | FILE_ATTRIBUTE_DIRECTORY))
== FILE_ATTRIBUTE_SYSTEM)
{
HANDLE sym_h;
status = NtOpenFile (&sym_h, SYNCHRONIZE | GENERIC_READ, &attr, &io,
FILE_SHARE_VALID_FLAGS,
FILE_OPEN_FOR_BACKUP_INTENT
| FILE_SYNCHRONOUS_IO_NONALERT);
if (!NT_SUCCESS (status))
res = 0;
else
{
res = check_sysfile (sym_h);
NtClose (sym_h);
}
if (res)
break;
}
/* If the file is on an NFS share and could be opened with extended
attributes, check if it's a symlink. Only files can be symlinks
(which can be symlinks to directories). */
else if (fs.is_nfs () && (conv_hdl.nfsattr ()->type & 7) == NF3LNK)
{
res = check_nfs_symlink (h);
if (res)
break;
}
/* Normal file. */
file_not_symlink:
issymlink = false;
syscall_printf ("%s", isdevice ? "is a device" : "not a symlink");
res = 0;
break;
}
if (h)
{
if (pflags & PC_KEEP_HANDLE)
conv_hdl.set (h);
else
NtClose (h);
}
syscall_printf ("%d = symlink.check(%s, %p) (%y)",
res, suffix.path, contents, pflags);
return res;
}
/* "path" is the path in a virtual symlink. Set a symlink_info struct from
that and proceed with further path checking afterwards. */
int
symlink_info::set (char *path)
{
strcpy (contents, path);
pflags = PATH_SYMLINK;
fileattr = FILE_ATTRIBUTE_NORMAL;
error = 0;
issymlink = true;
isdevice = false;
ext_tacked_on = false;
ext_here = NULL;
extn = major = minor = mode = 0;
return strlen (path);
}
/* readlink system call */
extern "C" ssize_t
readlink (const char *__restrict path, char *__restrict buf, size_t buflen)
{
if (buflen < 0)
{
set_errno (ENAMETOOLONG);
return -1;
}
path_conv pathbuf (path, PC_SYM_CONTENTS, stat_suffixes);
if (pathbuf.error)
{
set_errno (pathbuf.error);
syscall_printf ("-1 = readlink (%s, %p, %lu)", path, buf, buflen);
return -1;
}
if (!pathbuf.exists ())
{
set_errno (ENOENT);
return -1;
}
if (!pathbuf.issymlink ())
{
if (pathbuf.exists ())
set_errno (EINVAL);
return -1;
}
size_t pathbuf_len = strlen (pathbuf.get_win32 ());
ssize_t len = MIN (buflen, pathbuf_len);
memcpy (buf, pathbuf.get_win32 (), len);
/* errno set by symlink.check if error */
return len;
}
/* Some programs rely on st_dev/st_ino being unique for each file.
Hash the path name and hope for the best. The hash arg is not
always initialized to zero since readdir needs to compute the
dirent ino_t based on a combination of the hash of the directory
done during the opendir call and the hash or the filename within
the directory. FIXME: Not bullet-proof. */
/* Cygwin internal */
ino_t __reg2
hash_path_name (ino_t hash, PUNICODE_STRING name)
{
if (name->Length == 0)
return hash;
/* Build up hash. Name is already normalized */
USHORT len = name->Length / sizeof (WCHAR);
for (USHORT idx = 0; idx < len; ++idx)
hash = RtlUpcaseUnicodeChar (name->Buffer[idx])
+ (hash << 6) + (hash << 16) - hash;
return hash;
}
ino_t __reg2
hash_path_name (ino_t hash, PCWSTR name)
{
UNICODE_STRING uname;
RtlInitUnicodeString (&uname, name);
return hash_path_name (hash, &uname);
}
ino_t __reg2
hash_path_name (ino_t hash, const char *name)
{
UNICODE_STRING uname;
RtlCreateUnicodeStringFromAsciiz (&uname, name);
ino_t ret = hash_path_name (hash, &uname);
RtlFreeUnicodeString (&uname);
return ret;
}
extern "C" char *
getcwd (char *buf, size_t ulen)
{
char* res = NULL;
__try
{
if (ulen == 0 && buf)
set_errno (EINVAL);
else
res = cygheap->cwd.get (buf, 1, 1, ulen);
}
__except (EFAULT) {}
__endtry
return res;
}
/* getwd: Legacy. */
extern "C" char *
getwd (char *buf)
{
return getcwd (buf, PATH_MAX + 1); /*Per SuSv3!*/
}
extern "C" char *
get_current_dir_name (void)
{
const char *pwd = getenv ("PWD");
char *cwd = getcwd (NULL, 0);
struct stat pwdbuf, cwdbuf;
if (pwd && strcmp (pwd, cwd) != 0
&& stat64 (pwd, &pwdbuf) == 0
&& stat64 (cwd, &cwdbuf) == 0
&& pwdbuf.st_dev == cwdbuf.st_dev
&& pwdbuf.st_ino == cwdbuf.st_ino)
{
cwd = (char *) realloc (cwd, strlen (pwd) + 1);
strcpy (cwd, pwd);
}
return cwd;
}
/* chdir: POSIX 5.2.1.1 */
extern "C" int
chdir (const char *in_dir)
{
int res = -1;
__try
{
if (!*in_dir)
{
set_errno (ENOENT);
__leave;
}
syscall_printf ("dir '%s'", in_dir);
/* Convert path. First argument ensures that we don't check for
NULL/empty/invalid again. */
path_conv path (PC_NONULLEMPTY, in_dir, PC_SYM_FOLLOW | PC_POSIX);
if (path.error)
{
set_errno (path.error);
syscall_printf ("-1 = chdir (%s)", in_dir);
__leave;
}
const char *posix_cwd = NULL;
dev_t devn = path.get_device ();
if (!path.exists ())
set_errno (ENOENT);
else if (!path.isdir ())
set_errno (ENOTDIR);
else if (!isvirtual_dev (devn))
{
/* The sequence chdir("xx"); chdir(".."); must be a noop if xx
is not a symlink. This is exploited by find.exe.
The posix_cwd is just path.get_posix ().
In other cases we let cwd.set obtain the Posix path through
the mount table. */
if (!isdrive (path.get_posix ()))
posix_cwd = path.get_posix ();
res = 0;
}
else
{
posix_cwd = path.get_posix ();
res = 0;
}
if (!res)
res = cygheap->cwd.set (&path, posix_cwd);
/* Note that we're accessing cwd.posix without a lock here.
I didn't think it was worth locking just for strace. */
syscall_printf ("%R = chdir() cygheap->cwd.posix '%s' native '%S'", res,
cygheap->cwd.get_posix (), path.get_nt_native_path ());
}
__except (EFAULT)
{
res = -1;
}
__endtry
MALLOC_CHECK;
return res;
}
extern "C" int
fchdir (int fd)
{
int res;
cygheap_fdget cfd (fd);
if (cfd >= 0)
res = chdir (cfd->get_name ());
else
res = -1;
syscall_printf ("%R = fchdir(%d)", res, fd);
return res;
}
/******************** Exported Path Routines *********************/
/* Cover functions to the path conversion routines.
These are exported to the world as cygwin_foo by cygwin.din. */
#define return_with_errno(x) \
do {\
int err = (x);\
if (!err)\
return 0;\
set_errno (err);\
return -1;\
} while (0)
extern "C" ssize_t
cygwin_conv_path (cygwin_conv_path_t what, const void *from, void *to,
size_t size)
{
tmp_pathbuf tp;
path_conv p;
size_t lsiz = 0;
char *buf = NULL;
PWCHAR path = NULL;
int error = 0;
int how = what & ~CCP_CONVTYPE_MASK;
what &= CCP_CONVTYPE_MASK;
int ret = -1;
__try
{
if (!from)
{
set_errno (EINVAL);
__leave;
}
switch (what)
{
case CCP_POSIX_TO_WIN_A:
{
p.check ((const char *) from,
PC_POSIX | PC_SYM_FOLLOW | PC_SYM_NOFOLLOW_REP
| PC_NO_ACCESS_CHECK | PC_NOWARN
| ((how & CCP_RELATIVE) ? PC_NOFULL : 0));
if (p.error)
{
set_errno (p.error);
__leave;
}
PUNICODE_STRING up = p.get_nt_native_path ();
buf = tp.c_get ();
sys_wcstombs (buf, NT_MAX_PATH,
up->Buffer, up->Length / sizeof (WCHAR));
/* Convert native path to standard DOS path. */
if (!strncmp (buf, "\\??\\", 4))
{
buf += 4;
if (buf[1] != ':') /* native UNC path */
*(buf += 2) = '\\';
}
else if (*buf == '\\')
{
/* Device name points to somewhere else in the NT namespace.
Use GLOBALROOT prefix to convert to Win32 path. */
char *p = buf + sys_wcstombs (buf, NT_MAX_PATH,
ro_u_globalroot.Buffer,
ro_u_globalroot.Length
/ sizeof (WCHAR));
sys_wcstombs (p, NT_MAX_PATH - (p - buf),
up->Buffer, up->Length / sizeof (WCHAR));
}
lsiz = strlen (buf) + 1;
/* TODO: Incoming "." is a special case which leads to a trailing
backslash ".\\" in the Win32 path. That's a result of the
conversion in normalize_posix_path. This should not occur
so the below code is just a band-aid. */
if ((how & CCP_RELATIVE) && !strcmp ((const char *) from, ".")
&& !strcmp (buf, ".\\"))
{
lsiz = 2;
buf[1] = '\0';
}
}
break;
case CCP_POSIX_TO_WIN_W:
p.check ((const char *) from,
PC_POSIX | PC_SYM_FOLLOW | PC_SYM_NOFOLLOW_REP
| PC_NO_ACCESS_CHECK | PC_NOWARN
| ((how & CCP_RELATIVE) ? PC_NOFULL : 0));
if (p.error)
{
set_errno (p.error);
__leave;
}
/* Relative Windows paths are always restricted to MAX_PATH chars. */
if ((how & CCP_RELATIVE) && !isabspath (p.get_win32 ())
&& sys_mbstowcs (NULL, 0, p.get_win32 ()) > MAX_PATH)
{
/* Recreate as absolute path. */
p.check ((const char *) from, PC_POSIX | PC_SYM_FOLLOW
| PC_NO_ACCESS_CHECK | PC_NOWARN);
if (p.error)
{
set_errno (p.error);
__leave;
}
}
lsiz = p.get_wide_win32_path_len () + 1;
path = p.get_nt_native_path ()->Buffer;
/* Convert native path to standard DOS path. */
if (!wcsncmp (path, L"\\??\\", 4))
{
path[1] = L'\\';
/* Drop long path prefix for short pathnames. Unfortunately there's
quite a bunch of Win32 functions, especially in user32.dll,
apparently, which don't grok long path names at all, not even
in the UNICODE API. */
if ((path[5] == L':' && lsiz <= MAX_PATH + 4)
|| (!wcsncmp (path + 4, L"UNC\\", 4) && lsiz <= MAX_PATH + 6))
{
path += 4;
lsiz -= 4;
if (path[1] != L':')
{
*(path += 2) = '\\';
lsiz -= 2;
}
}
}
else if (*path == L'\\')
{
/* Device name points to somewhere else in the NT namespace.
Use GLOBALROOT prefix to convert to Win32 path. */
to = (void *) wcpcpy ((wchar_t *) to, ro_u_globalroot.Buffer);
lsiz += ro_u_globalroot.Length / sizeof (WCHAR);
}
/* TODO: Same ".\\" band-aid as in CCP_POSIX_TO_WIN_A case. */
if ((how & CCP_RELATIVE) && !strcmp ((const char *) from, ".")
&& !wcscmp (path, L".\\"))
{
lsiz = 2;
path[1] = L'\0';
}
lsiz *= sizeof (WCHAR);
break;
case CCP_WIN_A_TO_POSIX:
buf = tp.c_get ();
error = mount_table->conv_to_posix_path ((const char *) from, buf,
how);
if (error)
{
set_errno (p.error);
__leave;
}
lsiz = strlen (buf) + 1;
break;
case CCP_WIN_W_TO_POSIX:
buf = tp.c_get ();
error = mount_table->conv_to_posix_path ((const PWCHAR) from, buf,
how);
if (error)
{
set_errno (error);
__leave;
}
lsiz = strlen (buf) + 1;
break;
default:
set_errno (EINVAL);
__leave;
}
if (!size)
{
ret = lsiz;
__leave;
}
if (size < lsiz)
{
set_errno (ENOSPC);
__leave;
}
switch (what)
{
case CCP_POSIX_TO_WIN_A:
case CCP_WIN_A_TO_POSIX:
case CCP_WIN_W_TO_POSIX:
stpcpy ((char *) to, buf);
break;
case CCP_POSIX_TO_WIN_W:
wcpcpy ((PWCHAR) to, path);
break;
}
ret = 0;
}
__except (EFAULT) {}
__endtry
return ret;
}
extern "C" void *
cygwin_create_path (cygwin_conv_path_t what, const void *from)
{
void *to;
ssize_t size = cygwin_conv_path (what, from, NULL, 0);
if (size <= 0)
to = NULL;
else if (!(to = malloc (size)))
to = NULL;
if (cygwin_conv_path (what, from, to, size) == -1)
{
free (to);
to = NULL;
}
return to;
}
#ifndef __x86_64__ /* Disable deprecated functions on x86_64. */
extern "C" int
cygwin_conv_to_win32_path (const char *path, char *win32_path)
{
return cygwin_conv_path (CCP_POSIX_TO_WIN_A | CCP_RELATIVE, path, win32_path,
MAX_PATH);
}
extern "C" int
cygwin_conv_to_full_win32_path (const char *path, char *win32_path)
{
return cygwin_conv_path (CCP_POSIX_TO_WIN_A | CCP_ABSOLUTE, path, win32_path,
MAX_PATH);
}
/* This is exported to the world as cygwin_foo by cygwin.din. */
extern "C" int
cygwin_conv_to_posix_path (const char *path, char *posix_path)
{
return cygwin_conv_path (CCP_WIN_A_TO_POSIX | CCP_RELATIVE, path, posix_path,
MAX_PATH);
}
extern "C" int
cygwin_conv_to_full_posix_path (const char *path, char *posix_path)
{
return cygwin_conv_path (CCP_WIN_A_TO_POSIX | CCP_ABSOLUTE, path, posix_path,
MAX_PATH);
}
#endif /* !__x86_64__ */
/* The realpath function is required by POSIX:2008. */
extern "C" char *
realpath (const char *__restrict path, char *__restrict resolved)
{
tmp_pathbuf tp;
char *tpath;
/* Make sure the right errno is returned if path is NULL. */
if (!path)
{
set_errno (EINVAL);
return NULL;
}
/* Guard reading from a potentially invalid path and writing to a
potentially invalid resolved. */
__try
{
/* Win32 drive letter paths have to be converted to a POSIX path first,
because path_conv leaves the incoming path untouched except for
converting backslashes to forward slashes. */
if (isdrive (path))
{
tpath = tp.c_get ();
mount_table->conv_to_posix_path (path, tpath, 0);
}
else
tpath = (char *) path;
path_conv real_path (tpath, PC_SYM_FOLLOW | PC_POSIX, stat_suffixes);
/* POSIX 2008 requires malloc'ing if resolved is NULL, and states
that using non-NULL resolved is asking for portability
problems. */
if (!real_path.error && real_path.exists ())
{
if (!resolved)
{
resolved = (char *)
malloc (strlen (real_path.get_posix ()) + 1);
if (!resolved)
return NULL;
}
strcpy (resolved, real_path.get_posix ());
return resolved;
}
/* FIXME: on error, Linux puts the name of the path
component which could not be resolved into RESOLVED, but POSIX
does not require this. */
if (resolved)
resolved[0] = '\0';
set_errno (real_path.error ?: ENOENT);
}
__except (EFAULT) {}
__endtry
return NULL;
}
/* Linux provides this extension. Since the only portable use of
realpath requires a NULL second argument, we might as well have a
one-argument wrapper. */
extern "C" char *
canonicalize_file_name (const char *path)
{
return realpath (path, NULL);
}
/* Return non-zero if path is a POSIX path list.
This is exported to the world as cygwin_foo by cygwin.din.
DOCTOOL-START
<sect1 id="add-func-cygwin-posix-path-list-p">
<para>Rather than use a mode to say what the "proper" path list
format is, we allow any, and give apps the tools they need to
convert between the two. If a ';' is present in the path list it's
a Win32 path list. Otherwise, if the first path begins with
[letter]: (in which case it can be the only element since if it
wasn't a ';' would be present) it's a Win32 path list. Otherwise,
it's a POSIX path list.</para>
</sect1>
DOCTOOL-END
*/
extern "C" int
cygwin_posix_path_list_p (const char *path)
{
int posix_p = !(strchr (path, ';') || isdrive (path));
return posix_p;
}
/* These are used for apps that need to convert env vars like PATH back and
forth. The conversion is a two step process. First, an upper bound on the
size of the buffer needed is computed. Then the conversion is done. This
allows the caller to use alloca if it wants. */
static int
conv_path_list_buf_size (const char *path_list, bool to_posix)
{
int i, num_elms, max_mount_path_len, size;
const char *p;
path_conv pc(".", PC_POSIX);
/* The theory is that an upper bound is
current_size + (num_elms * max_mount_path_len) */
/* FIXME: This method is questionable in the long run. */
unsigned nrel;
char delim = to_posix ? ';' : ':';
for (p = path_list, num_elms = nrel = 0; p; num_elms++)
{
if (!isabspath (p))
nrel++;
p = strchr (++p, delim);
}
/* 7: strlen ("//c") + slop, a conservative initial value */
for (max_mount_path_len = sizeof ("/cygdrive/X"), i = 0;
i < mount_table->nmounts; i++)
{
int mount_len = (to_posix
? mount_table->mount[i].posix_pathlen
: mount_table->mount[i].native_pathlen);
if (max_mount_path_len < mount_len)
max_mount_path_len = mount_len;
}
/* 100: slop */
size = strlen (path_list)
+ (num_elms * max_mount_path_len)
+ (nrel * strlen (to_posix ? pc.get_posix () : pc.get_win32 ()))
+ 100;
return size;
}
extern "C" ssize_t
env_PATH_to_posix (const void *win32, void *posix, size_t size)
{
return_with_errno (conv_path_list ((const char *) win32, (char *) posix,
size, ENV_CVT));
}
#ifndef __x86_64__ /* Disable deprecated functions on x86_64. */
extern "C" int
cygwin_win32_to_posix_path_list_buf_size (const char *path_list)
{
return conv_path_list_buf_size (path_list, true);
}
extern "C" int
cygwin_posix_to_win32_path_list_buf_size (const char *path_list)
{
return conv_path_list_buf_size (path_list, false);
}
extern "C" int
cygwin_win32_to_posix_path_list (const char *win32, char *posix)
{
return_with_errno (conv_path_list (win32, posix, MAX_PATH,
CCP_WIN_A_TO_POSIX | CCP_RELATIVE));
}
extern "C" int
cygwin_posix_to_win32_path_list (const char *posix, char *win32)
{
return_with_errno (conv_path_list (posix, win32, MAX_PATH,
CCP_POSIX_TO_WIN_A | CCP_RELATIVE));
}
#endif /* !__x86_64__ */
extern "C" ssize_t
cygwin_conv_path_list (cygwin_conv_path_t what, const void *from, void *to,
size_t size)
{
int ret;
char *winp = NULL;
void *orig_to = NULL;
tmp_pathbuf tp;
switch (what & CCP_CONVTYPE_MASK)
{
case CCP_WIN_W_TO_POSIX:
if (!sys_wcstombs_alloc (&winp, HEAP_NOTHEAP, (const wchar_t *) from,
(size_t) -1))
return -1;
what = (what & ~CCP_CONVTYPE_MASK) | CCP_WIN_A_TO_POSIX;
from = (const void *) winp;
break;
case CCP_POSIX_TO_WIN_W:
if (size == 0)
return conv_path_list_buf_size ((const char *) from, 0)
* sizeof (WCHAR);
what = (what & ~CCP_CONVTYPE_MASK) | CCP_POSIX_TO_WIN_A;
orig_to = to;
to = (void *) tp.w_get ();
size = 65536;
break;
}
switch (what & CCP_CONVTYPE_MASK)
{
case CCP_WIN_A_TO_POSIX:
case CCP_POSIX_TO_WIN_A:
if (size == 0)
return conv_path_list_buf_size ((const char *) from,
what == CCP_WIN_A_TO_POSIX);
ret = conv_path_list ((const char *) from, (char *) to, size, what);
/* Free winp buffer in case of CCP_WIN_W_TO_POSIX. */
if (winp)
free (winp);
/* Convert to WCHAR in case of CCP_POSIX_TO_WIN_W. */
if (orig_to)
sys_mbstowcs ((wchar_t *) orig_to, size / sizeof (WCHAR),
(const char *) to, (size_t) -1);
return_with_errno (ret);
break;
default:
break;
}
set_errno (EINVAL);
return -1;
}
/* cygwin_split_path: Split a path into directory and file name parts.
Buffers DIR and FILE are assumed to be big enough.
Examples (path -> `dir' / `file'):
/ -> `/' / `'
"" -> `.' / `'
. -> `.' / `.' (FIXME: should this be `.' / `'?)
.. -> `.' / `..' (FIXME: should this be `..' / `'?)
foo -> `.' / `foo'
foo/bar -> `foo' / `bar'
foo/bar/ -> `foo' / `bar'
/foo -> `/' / `foo'
/foo/bar -> `/foo' / `bar'
c: -> `c:/' / `'
c:/ -> `c:/' / `'
c:foo -> `c:/' / `foo'
c:/foo -> `c:/' / `foo'
*/
extern "C" void
cygwin_split_path (const char *path, char *dir, char *file)
{
int dir_started_p = 0;
/* Deal with drives.
Remember that c:foo <==> c:/foo. */
if (isdrive (path))
{
*dir++ = *path++;
*dir++ = *path++;
*dir++ = '/';
if (!*path)
{
*dir = 0;
*file = 0;
return;
}
if (isdirsep (*path))
++path;
dir_started_p = 1;
}
/* Determine if there are trailing slashes and "delete" them if present.
We pretend as if they don't exist. */
const char *end = path + strlen (path);
/* path + 1: keep leading slash. */
while (end > path + 1 && isdirsep (end[-1]))
--end;
/* At this point, END points to one beyond the last character
(with trailing slashes "deleted"). */
/* Point LAST_SLASH at the last slash (duh...). */
const char *last_slash;
for (last_slash = end - 1; last_slash >= path; --last_slash)
if (isdirsep (*last_slash))
break;
if (last_slash == path)
{
*dir++ = '/';
*dir = 0;
}
else if (last_slash > path)
{
memcpy (dir, path, last_slash - path);
dir[last_slash - path] = 0;
}
else
{
if (dir_started_p)
; /* nothing to do */
else
*dir++ = '.';
*dir = 0;
}
memcpy (file, last_slash + 1, end - last_slash - 1);
file[end - last_slash - 1] = 0;
}
static inline void
copy_cwd_str (PUNICODE_STRING tgt, PUNICODE_STRING src)
{
RtlCopyUnicodeString (tgt, src);
if (tgt->Buffer[tgt->Length / sizeof (WCHAR) - 1] != L'\\')
{
tgt->Buffer[tgt->Length / sizeof (WCHAR)] = L'\\';
tgt->Length += sizeof (WCHAR);
}
}
/*****************************************************************************/
/* The find_fast_cwd_pointer function and parts of the
cwdstuff::override_win32_cwd method are based on code using the
following license:
Copyright 2010 John Carey. All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions
are met:
1. Redistributions of source code must retain the above
copyright notice, this list of conditions and the following
disclaimer.
2. Redistributions in binary form must reproduce the above
copyright notice, this list of conditions and the following
disclaimer in the documentation and/or other materials provided
with the distribution.
THIS SOFTWARE IS PROVIDED BY JOHN CAREY ``AS IS'' AND ANY EXPRESS
OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
ARE DISCLAIMED. IN NO EVENT SHALL JOHN CAREY OR CONTRIBUTORS BE
LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT
OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE
USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH
DAMAGE. */
void
fcwd_access_t::SetFSCharacteristics (LONG val)
{
/* Special case FSCharacteristics. Didn't exist originally. */
switch (fast_cwd_version ())
{
case FCWD_OLD:
break;
case FCWD_W7:
f7.FSCharacteristics = val;
break;
case FCWD_W8:
f8.FSCharacteristics = val;
break;
}
}
fcwd_version_t &
fcwd_access_t::fast_cwd_version ()
{
return cygheap->cwd.fast_cwd_version;
}
void
fcwd_access_t::CopyPath (UNICODE_STRING &target)
{
/* Copy the Path contents over into the UNICODE_STRING referenced by
target. This is used to set the CurrentDirectoryName in the
user parameter block. */
target = Path ();
}
void
fcwd_access_t::Free (PVOID heap)
{
/* Decrement the reference count. If it's down to 0, free
structure from heap. */
if (this && InterlockedDecrement (&ReferenceCount ()) == 0)
{
/* In contrast to pre-Vista, the handle on init is always a
fresh one and not the handle inherited from the parent
process. So we always have to close it here. However, the
handle could be NULL, if we cd'ed into a virtual dir. */
HANDLE h = DirectoryHandle ();
if (h)
NtClose (h);
RtlFreeHeap (heap, 0, this);
}
}
void
fcwd_access_t::FillIn (HANDLE dir, PUNICODE_STRING name,
ULONG old_dismount_count)
{
/* Fill in all values into this FAST_CWD structure. */
DirectoryHandle () = dir;
ReferenceCount () = 1;
OldDismountCount () = old_dismount_count;
/* The new structure stores the device characteristics of the
volume holding the dir. RtlGetCurrentDirectory_U checks
if the FILE_REMOVABLE_MEDIA flag is set and, if so, checks if
the volume is still the same as the one used when opening
the directory handle.
We don't call NtQueryVolumeInformationFile for the \\?\PIPE,
though. It just returns STATUS_INVALID_HANDLE anyway. */
if (fast_cwd_version () != FCWD_OLD)
{
SetFSCharacteristics (0);
if (name != &ro_u_pipedir)
{
IO_STATUS_BLOCK io;
FILE_FS_DEVICE_INFORMATION ffdi;
if (NT_SUCCESS (NtQueryVolumeInformationFile (dir, &io, &ffdi,
sizeof ffdi, FileFsDeviceInformation)))
SetFSCharacteristics (ffdi.Characteristics);
}
}
RtlInitEmptyUnicodeString (&Path (), Buffer (),
MAX_PATH * sizeof (WCHAR));
copy_cwd_str (&Path (), name);
}
void
fcwd_access_t::SetDirHandleFromBufferPointer (PWCHAR buf_p, HANDLE dir)
{
/* Input: The buffer pointer as it's stored in the user parameter block
and a directory handle.
This function computes the address to the FAST_CWD structure based
on the version and overwrites the directory handle. It is only
used if we couldn't figure out the address of fast_cwd_ptr. */
fcwd_access_t *f_cwd;
switch (fast_cwd_version ())
{
case FCWD_OLD:
default:
f_cwd = (fcwd_access_t *)
((PBYTE) buf_p - __builtin_offsetof (FAST_CWD_OLD, Buffer));
case FCWD_W7:
f_cwd = (fcwd_access_t *)
((PBYTE) buf_p - __builtin_offsetof (FAST_CWD_7, Buffer));
case FCWD_W8:
f_cwd = (fcwd_access_t *)
((PBYTE) buf_p - __builtin_offsetof (FAST_CWD_8, Buffer));
}
f_cwd->DirectoryHandle () = dir;
}
void
fcwd_access_t::SetVersionFromPointer (PBYTE buf_p, bool is_buffer)
{
/* Given a pointer to the FAST_CWD structure (is_buffer == false) or a
pointer to the Buffer within (is_buffer == true), this function
computes the FAST_CWD version by checking that Path.MaximumLength
equals MAX_PATH, and that Path.Buffer == Buffer. */
if (is_buffer)
buf_p -= __builtin_offsetof (FAST_CWD_8, Buffer);
fcwd_access_t *f_cwd = (fcwd_access_t *) buf_p;
if (f_cwd->f8.Path.MaximumLength == MAX_PATH * sizeof (WCHAR)
&& f_cwd->f8.Path.Buffer == f_cwd->f8.Buffer)
fast_cwd_version () = FCWD_W8;
else if (f_cwd->f7.Path.MaximumLength == MAX_PATH * sizeof (WCHAR)
&& f_cwd->f7.Path.Buffer == f_cwd->f7.Buffer)
fast_cwd_version () = FCWD_W7;
else
fast_cwd_version () = FCWD_OLD;
}
/* This function scans the code in ntdll.dll to find the address of the
global variable used to access the CWD starting with Vista. While the
pointer is global, it's not exported from the DLL, unfortunately.
Therefore we have to use some knowledge to figure out the address.
This code has been tested on Vista 32/64 bit, Server 2008 32/64 bit,
Windows 7 32/64 bit, Server 2008 R2 (which is only 64 bit anyway),
Windows 8 32/64 bit, Windows 8.1 32/64 bit, and Server 2012 R2. */
#ifdef __x86_64__
#define peek32(x) (*(int32_t *)(x))
static fcwd_access_t **
find_fast_cwd_pointer ()
{
/* Fetch entry points of relevant functions in ntdll.dll. */
HMODULE ntdll = GetModuleHandle ("ntdll.dll");
if (!ntdll)
return NULL;
const uint8_t *get_dir = (const uint8_t *)
GetProcAddress (ntdll, "RtlGetCurrentDirectory_U");
const uint8_t *ent_crit = (const uint8_t *)
GetProcAddress (ntdll, "RtlEnterCriticalSection");
if (!get_dir || !ent_crit)
return NULL;
/* Search first relative call instruction in RtlGetCurrentDirectory_U. */
const uint8_t *rcall = (const uint8_t *) memchr (get_dir, 0xe8, 40);
if (!rcall)
return NULL;
/* Fetch offset from instruction and compute address of called function.
This function actually fetches the current FAST_CWD instance and
performs some other actions, not important to us. */
const uint8_t *use_cwd = rcall + 5 + peek32 (rcall + 1);
/* Next we search for the locking mechanism and perform a sanity check.
On Pre-Windows 8 we basically look for the RtlEnterCriticalSection call.
Windows 8 does not call RtlEnterCriticalSection. The code manipulates
the FastPebLock manually, probably because RtlEnterCriticalSection has
been converted to an inline function. Either way, we test if the code
uses the FastPebLock. */
const uint8_t *movrbx;
const uint8_t *lock = (const uint8_t *)
memmem ((const char *) use_cwd, 80,
"\xf0\x0f\xba\x35", 4);
if (lock)
{
/* The lock instruction tweaks the LockCount member, which is not at
the start of the PRTL_CRITICAL_SECTION structure. So we have to
subtract the offset of LockCount to get the real address. */
PRTL_CRITICAL_SECTION lockaddr =
(PRTL_CRITICAL_SECTION) (lock + 9 + peek32 (lock + 4)
- offsetof (RTL_CRITICAL_SECTION, LockCount));
/* Test if lock address is FastPebLock. */
if (lockaddr != NtCurrentTeb ()->Peb->FastPebLock)
return NULL;
/* Search `mov rel(%rip),%rbx'. This is the instruction fetching the
address of the current fcwd_access_t pointer, and it should be pretty
near to the locking stuff. */
movrbx = (const uint8_t *) memmem ((const char *) lock, 40,
"\x48\x8b\x1d", 3);
}
else
{
/* Usually the callq RtlEnterCriticalSection follows right after
fetching the lock address. */
int call_rtl_offset = 7;
/* Search `lea rel(%rip),%rcx'. This loads the address of the lock into
%rcx for the subsequent RtlEnterCriticalSection call. */
lock = (const uint8_t *) memmem ((const char *) use_cwd, 80,
"\x48\x8d\x0d", 3);
if (!lock)
{
/* Windows 8.1 Preview calls `lea rel(rip),%r12' then some unrelated
or, then `mov %r12,%rcx', then `callq RtlEnterCriticalSection'. */
lock = (const uint8_t *) memmem ((const char *) use_cwd, 80,
"\x4c\x8d\x25", 3);
if (!lock)
return NULL;
call_rtl_offset = 14;
}
PRTL_CRITICAL_SECTION lockaddr =
(PRTL_CRITICAL_SECTION) (lock + 7 + peek32 (lock + 3));
/* Test if lock address is FastPebLock. */
if (lockaddr != NtCurrentTeb ()->Peb->FastPebLock)
return NULL;
/* Next is the `callq RtlEnterCriticalSection'. */
lock += call_rtl_offset;
if (lock[0] != 0xe8)
return NULL;
const uint8_t *call_addr = (const uint8_t *)
(lock + 5 + peek32 (lock + 1));
if (call_addr != ent_crit)
return NULL;
/* In contrast to the above Windows 8 code, we don't have to search
for the `mov rel(%rip),%rbx' instruction. It follows right after
the call to RtlEnterCriticalSection. */
movrbx = lock + 5;
}
if (!movrbx)
return NULL;
/* Check that the next instruction tests if the fetched value is NULL. */
const uint8_t *testrbx = (const uint8_t *)
memmem (movrbx + 7, 3, "\x48\x85\xdb", 3);
if (!testrbx)
return NULL;
/* Compute address of the fcwd_access_t ** pointer. */
return (fcwd_access_t **) (testrbx + peek32 (movrbx + 3));
}
#else
#define peek32(x) (*(uint32_t *)(x))
static fcwd_access_t **
find_fast_cwd_pointer ()
{
/* Fetch entry points of relevant functions in ntdll.dll. */
HMODULE ntdll = GetModuleHandle ("ntdll.dll");
if (!ntdll)
return NULL;
const uint8_t *get_dir = (const uint8_t *)
GetProcAddress (ntdll, "RtlGetCurrentDirectory_U");
const uint8_t *ent_crit = (const uint8_t *)
GetProcAddress (ntdll, "RtlEnterCriticalSection");
if (!get_dir || !ent_crit)
return NULL;
/* Search first relative call instruction in RtlGetCurrentDirectory_U. */
const uint8_t *rcall = (const uint8_t *) memchr (get_dir, 0xe8, 32);
if (!rcall)
return NULL;
/* Fetch offset from instruction and compute address of called function.
This function actually fetches the current FAST_CWD instance and
performs some other actions, not important to us. */
ptrdiff_t offset = (ptrdiff_t) peek32 (rcall + 1);
const uint8_t *use_cwd = rcall + 5 + offset;
/* Find first `push %edi' instruction. */
const uint8_t *pushedi = (const uint8_t *) memchr (use_cwd, 0x57, 32);
/* ...which should be followed by `mov crit-sect-addr,%edi' then
`push %edi', or by just a single `push crit-sect-addr'. */
const uint8_t *movedi = pushedi + 1;
const uint8_t *mov_pfast_cwd;
if (movedi[0] == 0x8b && movedi[1] == 0xff) /* mov %edi,%edi -> W8 */
{
/* Windows 8 does not call RtlEnterCriticalSection. The code manipulates
the FastPebLock manually, probably because RtlEnterCriticalSection has
been converted to an inline function.
Next we search for a `mov some address,%eax'. This address points
to the LockCount member of the FastPebLock structure, so the address
is equal to FastPebLock + 4. */
const uint8_t *moveax = (const uint8_t *) memchr (movedi, 0xb8, 16);
if (!moveax)
return NULL;
offset = (ptrdiff_t) peek32 (moveax + 1) - 4;
/* Compare the address with the known PEB lock as stored in the PEB. */
if ((PRTL_CRITICAL_SECTION) offset != NtCurrentTeb ()->Peb->FastPebLock)
return NULL;
/* Now search for the mov instruction fetching the address of the global
PFAST_CWD *. */
mov_pfast_cwd = moveax;
do
{
mov_pfast_cwd = (const uint8_t *) memchr (++mov_pfast_cwd, 0x8b, 48);
}
while (mov_pfast_cwd && mov_pfast_cwd[1] != 0x1d
&& (mov_pfast_cwd - moveax) < 48);
if (!mov_pfast_cwd || mov_pfast_cwd[1] != 0x1d)
return NULL;
}
else
{
if (movedi[0] == 0xbf && movedi[5] == 0x57)
rcall = movedi + 6;
else if (movedi[0] == 0x68)
rcall = movedi + 5;
else if (movedi[0] == 0x88 && movedi[4] == 0x83 && movedi[7] == 0x68)
{
/* Windows 8.1 Preview: The `mov lock_addr,%edi' is actually a
`mov %cl,15(%esp), followed by an `or #-1,%ebx, followed by a
`push lock_addr'. */
movedi += 7;
rcall = movedi + 5;
}
else
return NULL;
/* Compare the address used for the critical section with the known
PEB lock as stored in the PEB. */
if ((PRTL_CRITICAL_SECTION) peek32 (movedi + 1)
!= NtCurrentTeb ()->Peb->FastPebLock)
return NULL;
/* To check we are seeing the right code, we check our expectation that
the next instruction is a relative call into RtlEnterCriticalSection. */
if (rcall[0] != 0xe8)
return NULL;
/* Check that this is a relative call to RtlEnterCriticalSection. */
offset = (ptrdiff_t) peek32 (rcall + 1);
if (rcall + 5 + offset != ent_crit)
return NULL;
mov_pfast_cwd = rcall + 5;
}
/* After locking the critical section, the code should read the global
PFAST_CWD * pointer that is guarded by that critical section. */
if (mov_pfast_cwd[0] != 0x8b)
return NULL;
return (fcwd_access_t **) peek32 (mov_pfast_cwd + 2);
}
#endif
static fcwd_access_t **
find_fast_cwd ()
{
/* Fetch the pointer but don't set the global fast_cwd_ptr yet. First
we have to make sure we know the version of the FAST_CWD structure
used on the system. */
fcwd_access_t **f_cwd_ptr = find_fast_cwd_pointer ();
if (!f_cwd_ptr)
small_printf ("Cygwin WARNING:\n"
" Couldn't compute FAST_CWD pointer. This typically occurs if you're using\n"
" an older Cygwin version on a newer Windows. Please update to the latest\n"
" available Cygwin version from https://cygwin.com/. If the problem persists,\n"
" please see https://cygwin.com/problems.html\n\n");
if (f_cwd_ptr && *f_cwd_ptr)
{
/* Just evaluate structure version. */
fcwd_access_t::SetVersionFromPointer ((PBYTE) *f_cwd_ptr, false);
}
else
{
/* If we couldn't fetch fast_cwd_ptr, or if fast_cwd_ptr is NULL(*)
we have to figure out the version from the Buffer pointer in the
ProcessParameters.
(*) This is very unlikely to happen when starting the first
Cygwin process, since it only happens when starting the
process in a directory which can't be used as CWD by Win32, or
if the directory doesn't exist. But *if* it happens, we have
no valid FAST_CWD structure, even though upp_cwd_str.Buffer is
not NULL in that case. So we let the OS create a valid
FAST_CWD structure temporarily to have something to work with.
We know the pipe FS works. */
PEB &peb = *NtCurrentTeb ()->Peb;
if (f_cwd_ptr /* so *f_cwd_ptr == NULL */
&& !NT_SUCCESS (RtlSetCurrentDirectory_U (&ro_u_pipedir)))
api_fatal ("Couldn't set directory to %S temporarily.\n"
"Cannot continue.", &ro_u_pipedir);
RtlEnterCriticalSection (peb.FastPebLock);
fcwd_access_t::SetVersionFromPointer
((PBYTE) peb.ProcessParameters->CurrentDirectoryName.Buffer, true);
RtlLeaveCriticalSection (peb.FastPebLock);
}
/* Eventually, after we set the version as well, set fast_cwd_ptr. */
return f_cwd_ptr;
}
void
cwdstuff::override_win32_cwd (bool init, ULONG old_dismount_count)
{
HANDLE h = NULL;
PEB &peb = *NtCurrentTeb ()->Peb;
UNICODE_STRING &upp_cwd_str = peb.ProcessParameters->CurrentDirectoryName;
HANDLE &upp_cwd_hdl = peb.ProcessParameters->CurrentDirectoryHandle;
if (wincap.has_fast_cwd ())
{
if (fast_cwd_ptr == (fcwd_access_t **) -1)
fast_cwd_ptr = find_fast_cwd ();
if (fast_cwd_ptr)
{
/* Default method starting with Vista. If we got a valid value for
fast_cwd_ptr, we can simply replace the RtlSetCurrentDirectory_U
function entirely, just as on pre-Vista. */
PVOID heap = peb.ProcessHeap;
/* First allocate a new fcwd_access_t structure on the heap.
The new fcwd_access_t structure is 4 byte bigger than the old one,
but we simply don't care, so we allocate always room for the
new one. */
fcwd_access_t *f_cwd = (fcwd_access_t *)
RtlAllocateHeap (heap, 0, sizeof (fcwd_access_t));
if (!f_cwd)
{
debug_printf ("RtlAllocateHeap failed");
return;
}
/* Fill in the values. */
f_cwd->FillIn (dir, error ? &ro_u_pipedir : &win32,
old_dismount_count);
/* Use PEB lock when switching fast_cwd_ptr to the new FAST_CWD
structure and writing the CWD to the user process parameter
block. This is equivalent to calling RtlAcquirePebLock/
RtlReleasePebLock, but without having to go through the FS
selector again. */
RtlEnterCriticalSection (peb.FastPebLock);
fcwd_access_t *old_cwd = *fast_cwd_ptr;
*fast_cwd_ptr = f_cwd;
f_cwd->CopyPath (upp_cwd_str);
upp_cwd_hdl = dir;
RtlLeaveCriticalSection (peb.FastPebLock);
old_cwd->Free (heap);
}
else
{
/* This is more a hack, and it's only used on Vista and later if we
failed to find the fast_cwd_ptr value. What we do here is to call
RtlSetCurrentDirectory_U and let it set up a new FAST_CWD
structure. Afterwards, compute the address of that structure
utilizing the fact that the buffer address in the user process
parameter block is actually pointing to the buffer in that
FAST_CWD structure. Then replace the directory handle in that
structure with our own handle and close the original one.
Note that the call to RtlSetCurrentDirectory_U also closes our
old dir handle, so there won't be any handle left open.
This method is prone to two race conditions:
- Due to the way RtlSetCurrentDirectory_U opens the directory
handle, the directory is locked against deletion or renaming
between the RtlSetCurrentDirectory_U and the subsequent NtClose
call.
- When another thread calls SetCurrentDirectory at exactly the
same time, a crash might occur, or worse, unrelated data could
be overwritten or NtClose could be called on an unrelated handle.
Therefore, use this *only* as a fallback. */
if (!init)
{
NTSTATUS status =
RtlSetCurrentDirectory_U (error ? &ro_u_pipedir : &win32);
if (!NT_SUCCESS (status))
{
debug_printf ("RtlSetCurrentDirectory_U(%S) failed, %y",
error ? &ro_u_pipedir : &win32, status);
return;
}
}
else if (upp_cwd_hdl == NULL)
return;
RtlEnterCriticalSection (peb.FastPebLock);
fcwd_access_t::SetDirHandleFromBufferPointer(upp_cwd_str.Buffer, dir);
h = upp_cwd_hdl;
upp_cwd_hdl = dir;
RtlLeaveCriticalSection (peb.FastPebLock);
/* In contrast to pre-Vista, the handle on init is always a fresh one
and not the handle inherited from the parent process. So we always
have to close it here. */
NtClose (h);
}
}
else
{
/* This method is used for all pre-Vista OSes. We simply set the values
for the CWD in the user process parameter block entirely by ourselves
under PEB lock condition. This is how RtlSetCurrentDirectory_U worked
in these older OSes, so we're safe.
Note that we can't just RtlEnterCriticalSection (peb.FastPebLock)
on pre-Vista. RtlAcquirePebLock was way more complicated back then. */
RtlAcquirePebLock ();
if (!init)
copy_cwd_str (&upp_cwd_str, error ? &ro_u_pipedir : &win32);
h = upp_cwd_hdl;
upp_cwd_hdl = dir;
RtlReleasePebLock ();
/* Only on init, the handle is potentially a native handle. However,
if it's identical to dir, it's the inherited handle from a Cygwin
parent process and must not be closed. */
if (h && h != dir)
NtClose (h);
}
}
/* Initialize cygcwd 'muto' for serializing access to cwd info. */
void
cwdstuff::init ()
{
cwd_lock.init ("cwd_lock");
/* Cygwin processes inherit the cwd from their parent. If the win32 path
buffer is not NULL, the cwd struct is already set up, and we only
have to override the Win32 CWD with ours. */
if (win32.Buffer)
override_win32_cwd (true, SharedUserData.DismountCount);
else
{
/* Initialize fast_cwd stuff. */
fast_cwd_ptr = (fcwd_access_t **) -1;
fast_cwd_version = FCWD_W7;
/* Initially re-open the cwd to allow POSIX semantics. */
set (NULL, NULL);
}
}
/* Chdir and fill out the elements of a cwdstuff struct. */
int
cwdstuff::set (path_conv *nat_cwd, const char *posix_cwd)
{
NTSTATUS status;
UNICODE_STRING upath;
PEB &peb = *NtCurrentTeb ()->Peb;
bool virtual_path = false;
bool unc_path = false;
bool inaccessible_path = false;
/* Here are the problems with using SetCurrentDirectory. Just skip this
comment if you don't like whining.
- SetCurrentDirectory only supports paths of up to MAX_PATH - 1 chars,
including a trailing backslash. That's an absolute restriction, even
in the UNICODE API.
- SetCurrentDirectory fails for directories with strict permissions even
for processes with the SE_BACKUP_NAME privilege enabled. The reason
is apparently that SetCurrentDirectory calls NtOpenFile without the
FILE_OPEN_FOR_BACKUP_INTENT flag set.
- SetCurrentDirectory does not support case-sensitivity.
- Unlinking a cwd fails because SetCurrentDirectory seems to open
directories so that deleting the directory is disallowed.
- SetCurrentDirectory can naturally not work on virtual Cygwin paths
like /proc or /cygdrive.
Unfortunately, even though we have access to the Win32 process parameter
block, we can't just replace the directory handle. Starting with Vista,
the handle is used elsewhere, and just replacing the handle in the process
parameter block shows quite surprising results.
FIXME: If we ever find a *safe* way to replace the directory handle in
the process parameter block, we're back in business.
Nevertheless, doing entirely without SetCurrentDirectory is not really
feasible, because it breaks too many mixed applications using the Win32
API.
Therefore we handle the CWD all by ourselves and just keep the Win32
CWD in sync. However, to avoid surprising behaviour in the Win32 API
when we are in a CWD which is inaccessible as Win32 CWD, we set the
Win32 CWD to a "weird" directory in which all relative filesystem-related
calls fail. */
cwd_lock.acquire ();
if (nat_cwd)
{
upath = *nat_cwd->get_nt_native_path ();
if (nat_cwd->isspecial ())
virtual_path = true;
}
/* Memorize old DismountCount before opening the dir. This value is
stored in the FAST_CWD structure on Vista and later. It would be
simpler to fetch the old DismountCount in override_win32_cwd, but
Windows also fetches it before opening the directory handle. It's
not quite clear if that's really required, but since we don't know
the side effects of this action, we better follow Windows' lead. */
ULONG old_dismount_count = SharedUserData.DismountCount;
/* Open a directory handle with FILE_OPEN_FOR_BACKUP_INTENT and with all
sharing flags set. The handle is right now used in exceptions.cc only,
but that might change in future. */
HANDLE h = NULL;
if (!virtual_path)
{
IO_STATUS_BLOCK io;
OBJECT_ATTRIBUTES attr;
if (!nat_cwd)
{
/* On init, just reopen Win32 CWD with desired access flags.
We can access the PEB without lock, because no other thread
can change the CWD. */
RtlInitUnicodeString (&upath, L"");
InitializeObjectAttributes (&attr, &upath,
OBJ_CASE_INSENSITIVE | OBJ_INHERIT,
peb.ProcessParameters->CurrentDirectoryHandle, NULL);
}
else
InitializeObjectAttributes (&attr, &upath,
nat_cwd->objcaseinsensitive () | OBJ_INHERIT,
NULL, NULL);
/* First try without FILE_OPEN_FOR_BACKUP_INTENT, to find out if the
directory is valid for Win32 apps. And, no, we can't just call
SetCurrentDirectory here, since that would potentially break
case-sensitivity. */
status = NtOpenFile (&h, SYNCHRONIZE | FILE_TRAVERSE, &attr, &io,
FILE_SHARE_VALID_FLAGS,
FILE_DIRECTORY_FILE
| FILE_SYNCHRONOUS_IO_NONALERT);
if (status == STATUS_ACCESS_DENIED)
{
status = NtOpenFile (&h, SYNCHRONIZE | FILE_TRAVERSE, &attr, &io,
FILE_SHARE_VALID_FLAGS,
FILE_DIRECTORY_FILE
| FILE_SYNCHRONOUS_IO_NONALERT
| FILE_OPEN_FOR_BACKUP_INTENT);
inaccessible_path = true;
}
if (!NT_SUCCESS (status))
{
cwd_lock.release ();
__seterrno_from_nt_status (status);
return -1;
}
}
/* Set new handle. Note that we simply overwrite the old handle here
without closing it. The handle is also used as Win32 CWD handle in
the user parameter block, and it will be closed in override_win32_cwd,
if required. */
dir = h;
if (!nat_cwd)
{
/* On init, just fetch the Win32 dir from the PEB. We can access
the PEB without lock, because no other thread can change the CWD
at that time. */
PUNICODE_STRING pdir = &peb.ProcessParameters->CurrentDirectoryName;
RtlInitEmptyUnicodeString (&win32,
(PWCHAR) crealloc_abort (win32.Buffer,
pdir->Length
+ sizeof (WCHAR)),
pdir->Length + sizeof (WCHAR));
RtlCopyUnicodeString (&win32, pdir);
PWSTR eoBuffer = win32.Buffer + (win32.Length / sizeof (WCHAR));
/* Remove trailing slash if one exists. */
if ((eoBuffer - win32.Buffer) > 3 && eoBuffer[-1] == L'\\')
win32.Length -= sizeof (WCHAR);
if (eoBuffer[0] == L'\\')
unc_path = true;
posix_cwd = NULL;
}
else
{
if (!virtual_path) /* don't mangle virtual path. */
{
/* Convert into Win32 path and compute length. */
if (upath.Buffer[1] == L'?')
{
upath.Buffer += 4;
upath.Length -= 4 * sizeof (WCHAR);
if (upath.Buffer[1] != L':')
{
/* UNC path */
upath.Buffer += 2;
upath.Length -= 2 * sizeof (WCHAR);
unc_path = true;
}
}
else
{
/* Path via native NT namespace. Prepend GLOBALROOT prefix
to create a valid Win32 path. */
PWCHAR buf = (PWCHAR) alloca (upath.Length
+ ro_u_globalroot.Length
+ sizeof (WCHAR));
wcpcpy (wcpcpy (buf, ro_u_globalroot.Buffer), upath.Buffer);
upath.Buffer = buf;
upath.Length += ro_u_globalroot.Length;
}
PWSTR eoBuffer = upath.Buffer + (upath.Length / sizeof (WCHAR));
/* Remove trailing slash if one exists. */
if ((eoBuffer - upath.Buffer) > 3 && eoBuffer[-1] == L'\\')
upath.Length -= sizeof (WCHAR);
}
RtlInitEmptyUnicodeString (&win32,
(PWCHAR) crealloc_abort (win32.Buffer,
upath.Length
+ sizeof (WCHAR)),
upath.Length + sizeof (WCHAR));
RtlCopyUnicodeString (&win32, &upath);
if (unc_path)
win32.Buffer[0] = L'\\';
}
/* Make sure it's NUL-terminated. */
win32.Buffer[win32.Length / sizeof (WCHAR)] = L'\0';
/* Set drive_length, used in path conversion, and error code, used in
spawn_guts to decide whether a native Win32 app can be started or not. */
if (virtual_path)
{
drive_length = 0;
error = ENOTDIR;
}
else
{
if (!unc_path)
drive_length = 2;
else
{
PWCHAR ptr = wcschr (win32.Buffer + 2, L'\\');
if (ptr)
ptr = wcschr (ptr + 1, L'\\');
if (ptr)
drive_length = ptr - win32.Buffer;
else
drive_length = win32.Length / sizeof (WCHAR);
}
if (inaccessible_path)
error = EACCES;
else if (win32.Length > (MAX_PATH - 2) * sizeof (WCHAR))
error = ENAMETOOLONG;
else
error = 0;
}
/* Keep the Win32 CWD in sync. Don't check for error, other than for
strace output. Try to keep overhead low. */
override_win32_cwd (!nat_cwd, old_dismount_count);
/* Eventually, create POSIX path if it's not set on entry. */
tmp_pathbuf tp;
if (!posix_cwd)
{
posix_cwd = (const char *) tp.c_get ();
mount_table->conv_to_posix_path (win32.Buffer, (char *) posix_cwd, 0);
}
posix = (char *) crealloc_abort (posix, strlen (posix_cwd) + 1);
stpcpy (posix, posix_cwd);
cwd_lock.release ();
return 0;
}
const char *
cwdstuff::get_error_desc () const
{
switch (cygheap->cwd.get_error ())
{
case EACCES:
return "has restricted permissions which render it\n"
"inaccessible as Win32 working directory";
case ENOTDIR:
return "is a virtual Cygwin directory which does\n"
"not exist for a native Windows application";
case ENAMETOOLONG:
return "has a path longer than allowed for a\n"
"Win32 working directory";
default:
break;
}
/* That shouldn't occur, unless we defined a new error code
in cwdstuff::set. */
return "is not accessible for some unknown reason";
}
/* Store incoming wchar_t path as current posix cwd. This is called from
setlocale so that the cwd is always stored in the right charset. */
void
cwdstuff::reset_posix (wchar_t *w_cwd)
{
size_t len = sys_wcstombs (NULL, (size_t) -1, w_cwd);
posix = (char *) crealloc_abort (posix, len + 1);
sys_wcstombs (posix, len + 1, w_cwd);
}
char *
cwdstuff::get (char *buf, int need_posix, int with_chroot, unsigned ulen)
{
MALLOC_CHECK;
tmp_pathbuf tp;
if (ulen)
/* nothing */;
else if (buf == NULL)
ulen = (unsigned) -1;
else
{
set_errno (EINVAL);
goto out;
}
cwd_lock.acquire ();
char *tocopy;
if (!need_posix)
{
tocopy = tp.c_get ();
sys_wcstombs (tocopy, NT_MAX_PATH, win32.Buffer,
win32.Length / sizeof (WCHAR));
}
else
tocopy = posix;
debug_printf ("posix %s", posix);
if (strlen (tocopy) >= ulen)
{
set_errno (ERANGE);
buf = NULL;
}
else
{
if (!buf)
buf = (char *) malloc (strlen (tocopy) + 1);
strcpy (buf, tocopy);
if (!buf[0]) /* Should only happen when chroot */
strcpy (buf, "/");
}
cwd_lock.release ();
out:
syscall_printf ("(%s) = cwdstuff::get (%p, %u, %d, %d), errno %d",
buf, buf, ulen, need_posix, with_chroot, errno);
MALLOC_CHECK;
return buf;
}
/* No need to be reentrant or thread-safe according to SUSv3.
/ and \\ are treated equally. Leading drive specifiers are
kept intact as far as it makes sense. Everything else is
POSIX compatible. */
extern "C" char *
basename (char *path)
{
static char buf[4];
char *c, *d, *bs = path;
if (!path || !*path)
return strcpy (buf, ".");
if (isalpha (path[0]) && path[1] == ':')
bs += 2;
else if (strspn (path, "/\\") > 1)
++bs;
c = strrchr (bs, '/');
if ((d = strrchr (c ?: bs, '\\')) > c)
c = d;
if (c)
{
/* Trailing (back)slashes are eliminated. */
while (c && c > bs && c[1] == '\0')
{
*c = '\0';
c = strrchr (bs, '/');
if ((d = strrchr (c ?: bs, '\\')) > c)
c = d;
}
if (c && (c > bs || c[1]))
return c + 1;
}
else if (!bs[0])
{
stpncpy (buf, path, bs - path);
stpcpy (buf + (bs - path), ".");
return buf;
}
return path;
}
/* The differences with the POSIX version above:
- declared in <string.h> (instead of <libgen.h>);
- the argument is never modified, and therefore is marked const;
- the empty string is returned if path is an empty string, "/", or ends
with a trailing slash. */
extern "C" char *
__gnu_basename (const char *path)
{
static char buf[1];
char *c, *d, *bs = (char *)path;
if (!path || !*path)
return strcpy (buf, "");
if (isalpha (path[0]) && path[1] == ':')
bs += 2;
else if (strspn (path, "/\\") > 1)
++bs;
c = strrchr (bs, '/');
if ((d = strrchr (c ?: bs, '\\')) > c)
c = d;
if (c)
return c + 1;
else if (!bs[0])
return strcpy (buf, "");
return (char *)path;
}
/* No need to be reentrant or thread-safe according to SUSv3.
/ and \\ are treated equally. Leading drive specifiers and
leading double (back)slashes are kept intact as far as it
makes sense. Everything else is POSIX compatible. */
extern "C" char *
dirname (char *path)
{
static char buf[4];
char *c, *d, *bs = path;
if (!path || !*path)
return strcpy (buf, ".");
if (isalpha (path[0]) && path[1] == ':')
bs += 2;
else if (strspn (path, "/\\") > 1)
++bs;
c = strrchr (bs, '/');
if ((d = strrchr (c ?: bs, '\\')) > c)
c = d;
if (c)
{
/* Trailing (back)slashes are eliminated. */
while (c && c > bs && c[1] == '\0')
{
*c = '\0';
c = strrchr (bs, '/');
if ((d = strrchr (c ?: bs, '\\')) > c)
c = d;
}
if (!c)
strcpy (bs, ".");
else if (c > bs)
{
/* More trailing (back)slashes are eliminated. */
while (c > bs && (*c == '/' || *c == '\\'))
*c-- = '\0';
}
else
c[1] = '\0';
}
else
{
stpncpy (buf, path, bs - path);
stpcpy (buf + (bs - path), ".");
return buf;
}
return path;
}