/* syscalls.cc: syscalls Copyright 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010, 2011, 2012, 2013, 2014 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. */ #define fstat __FOOfstat__ #define lstat __FOOlstat__ //#define stat __FOOstat__ #define _close __FOO_close__ #define _lseek __FOO_lseek__ #define _open __FOO_open__ #define _read __FOO_read__ #define _write __FOO_write__ #define _open64 __FOO_open64__ #define _lseek64 __FOO_lseek64__ #define _fstat64 __FOO_fstat64__ #define pread __FOO_pread #define pwrite __FOO_pwrite #include "winsup.h" #include "miscfuncs.h" #include #include /* needed for statfs */ #include /* needed for statvfs */ #include #include #include #include #include #include #include #include #include #include #include #include "ntdll.h" #undef fstat #undef lstat //#undef stat #undef pread #undef pwrite #include #include "cygerrno.h" #include "perprocess.h" #include "security.h" #include "path.h" #include "fhandler.h" #include "dtable.h" #include "sigproc.h" #include "pinfo.h" #include "shared_info.h" #include "cygheap.h" #include "registry.h" #include "environ.h" #include "tls_pbuf.h" #include "sync.h" #include "child_info.h" #undef _close #undef _lseek #undef _open #undef _read #undef _write #undef _open64 #undef _lseek64 #undef _fstat64 static int __stdcall mknod_worker (const char *, mode_t, mode_t, _major_t, _minor_t); /* Close all files and process any queued deletions. Lots of unix style applications will open a tmp file, unlink it, but never call close. This function is called by _exit to ensure we don't leave any such files lying around. */ void __stdcall close_all_files (bool norelease) { cygheap->fdtab.lock (); semaphore::terminate (); HANDLE h = NULL; for (int i = 0; i < (int) cygheap->fdtab.size; i++) { cygheap_fdget cfd (i, false, false); if (cfd >= 0) { debug_only_printf ("closing fd %d", i); if (i == 2) DuplicateHandle (GetCurrentProcess (), cfd->get_output_handle (), GetCurrentProcess (), &h, 0, false, DUPLICATE_SAME_ACCESS); cfd->close_with_arch (); if (!norelease) cfd.release (); } } if (!have_execed && cygheap->ctty) cygheap->close_ctty (); fhandler_base_overlapped::flush_all_async_io (); if (h) SetStdHandle (STD_ERROR_HANDLE, h); cygheap->fdtab.unlock (); } extern "C" int dup (int fd) { int res; cygheap_fdnew newfd; if (newfd < 0) res = -1; else res = cygheap->fdtab.dup3 (fd, newfd, 0); syscall_printf ("%R = dup(%d)", res, fd); return res; } inline int dup_finish (int oldfd, int newfd, int flags) { int res; if ((res = cygheap->fdtab.dup3 (oldfd, newfd, flags | O_EXCL)) == newfd) { cygheap_fdget (newfd)->inc_refcnt (); cygheap->fdtab.unlock (); /* dup3 exits with lock set on success */ } return res; } extern "C" int dup2 (int oldfd, int newfd) { int res; if (newfd >= OPEN_MAX_MAX || newfd < 0) { set_errno (EBADF); res = -1; } else if (newfd == oldfd) { cygheap_fdget cfd (oldfd); res = (cfd >= 0) ? oldfd : -1; } else res = dup_finish (oldfd, newfd, 0); syscall_printf ("%R = dup2(%d, %d)", res, oldfd, newfd); return res; } extern "C" int dup3 (int oldfd, int newfd, int flags) { int res; if (newfd >= OPEN_MAX_MAX) { set_errno (EBADF); res = -1; } else if (newfd == oldfd) { cygheap_fdget cfd (oldfd, false, false); set_errno (cfd < 0 ? EBADF : EINVAL); res = -1; } else res = dup_finish (oldfd, newfd, flags); syscall_printf ("%R = dup3(%d, %d, %y)", res, oldfd, newfd, flags); return res; } /* Define macro to simplify checking for a transactional error code. */ #define NT_TRANSACTIONAL_ERROR(s) \ (((ULONG)(s) >= (ULONG)STATUS_TRANSACTIONAL_CONFLICT) \ && ((ULONG)(s) <= (ULONG)STATUS_TRANSACTION_NOT_ENLISTED)) static inline void start_transaction (HANDLE &old_trans, HANDLE &trans) { NTSTATUS status = NtCreateTransaction (&trans, SYNCHRONIZE | TRANSACTION_ALL_ACCESS, NULL, NULL, NULL, 0, 0, 0, NULL, NULL); if (NT_SUCCESS (status)) { old_trans = RtlGetCurrentTransaction (); RtlSetCurrentTransaction (trans); } else { debug_printf ("NtCreateTransaction failed, %y", status); old_trans = trans = NULL; } } static inline NTSTATUS stop_transaction (NTSTATUS status, HANDLE old_trans, HANDLE &trans) { RtlSetCurrentTransaction (old_trans); if (NT_SUCCESS (status)) status = NtCommitTransaction (trans, TRUE); else status = NtRollbackTransaction (trans, TRUE); NtClose (trans); trans = NULL; return status; } static char desktop_ini[] = "[.ShellClassInfo]\r\n" "CLSID={645FF040-5081-101B-9F08-00AA002F954E}\r\n"; static char desktop_ini_ext[] = "LocalizedResourceName=@%SystemRoot%\\system32\\shell32.dll,-8964\r\n"; static BYTE info2[] = { 0x05, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x20, 0x03, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }; enum bin_status { dont_move, move_to_bin, has_been_moved, dir_not_empty }; static bin_status try_to_bin (path_conv &pc, HANDLE &fh, ACCESS_MASK access, ULONG flags) { bin_status bin_stat = move_to_bin; NTSTATUS status; OBJECT_ATTRIBUTES attr; IO_STATUS_BLOCK io; HANDLE rootdir = NULL, recyclerdir = NULL, tmp_fh = NULL; USHORT recycler_base_len = 0, recycler_user_len = 0; UNICODE_STRING root, recycler, fname; WCHAR recyclerbuf[NAME_MAX + 1]; /* Enough for recycler + SID + filename */ PFILE_NAME_INFORMATION pfni; PFILE_INTERNAL_INFORMATION pfii; PFILE_RENAME_INFORMATION pfri; ULONG frisiz; FILE_DISPOSITION_INFORMATION disp = { TRUE }; bool fs_has_per_user_recycler = pc.fs_is_ntfs () || pc.fs_is_refs (); tmp_pathbuf tp; PBYTE infobuf = (PBYTE) tp.w_get (); pfni = (PFILE_NAME_INFORMATION) infobuf; status = NtQueryInformationFile (fh, &io, pfni, 65536, FileNameInformation); if (!NT_SUCCESS (status)) { debug_printf ("NtQueryInformationFile (%S, FileNameInformation) " "failed, status = %y", pc.get_nt_native_path (), status); goto out; } /* The filename could change, the parent dir not. So we split both paths and take the prefix. However, there are two special cases: - The handle refers to the root dir of the volume. - The handle refers to the recycler or a subdir. Both cases are handled by just returning and not even trying to move them into the recycler. */ if (pfni->FileNameLength == 2) /* root dir. */ goto out; /* The recycler name on Vista and later is $Recycler.Bin by default. If the recycler dir disappeared for some reason, the shell32.dll recreates the directory in all upper case. So, we never know beforehand if the dir is written in mixed case or in all upper case. That's a problem when using casesensitivity. If the file handle given to FileRenameInformation has been opened casesensitive, the call also handles the path to the target dir casesensitive. Rather then trying to find the right name of the recycler, we just reopen the file to move with OBJ_CASE_INSENSITIVE, so the subsequent FileRenameInformation works caseinsensitive in terms of the recycler directory name, too. */ if (!pc.objcaseinsensitive ()) { InitializeObjectAttributes (&attr, &ro_u_empty, OBJ_CASE_INSENSITIVE, fh, NULL); status = NtOpenFile (&tmp_fh, access, &attr, &io, FILE_SHARE_VALID_FLAGS, flags); if (!NT_SUCCESS (status)) debug_printf ("NtOpenFile (%S) for reopening caseinsensitive failed, " "status = %y", pc.get_nt_native_path (), status); else { NtClose (fh); fh = tmp_fh; } } /* Initialize recycler path. */ RtlInitEmptyUnicodeString (&recycler, recyclerbuf, sizeof recyclerbuf); if (!pc.isremote ()) { if (wincap.has_recycle_dot_bin ()) /* NTFS and FAT since Vista, ReFS */ RtlAppendUnicodeToString (&recycler, L"\\$Recycle.Bin\\"); else if (pc.fs_is_ntfs ()) /* NTFS up to 2K3 */ RtlAppendUnicodeToString (&recycler, L"\\RECYCLER\\"); else if (pc.fs_is_fat ()) /* FAT up to 2K3 */ RtlAppendUnicodeToString (&recycler, L"\\Recycled\\"); else goto out; /* Is the file a subdir of the recycler? */ RtlInitCountedUnicodeString(&fname, pfni->FileName, pfni->FileNameLength); if (RtlEqualUnicodePathPrefix (&fname, &recycler, TRUE)) goto out; /* Is fname the recycler? Temporarily hide trailing backslash. */ recycler.Length -= sizeof (WCHAR); if (RtlEqualUnicodeString (&fname, &recycler, TRUE)) goto out; /* Create root dir path from file name information. */ RtlSplitUnicodePath (&fname, &fname, NULL); RtlSplitUnicodePath (pc.get_nt_native_path (), &root, NULL); root.Length -= fname.Length - sizeof (WCHAR); /* Open root directory. All recycler bin ops are caseinsensitive. */ InitializeObjectAttributes (&attr, &root, OBJ_CASE_INSENSITIVE, NULL, NULL); status = NtOpenFile (&rootdir, FILE_TRAVERSE, &attr, &io, FILE_SHARE_VALID_FLAGS, FILE_OPEN_FOR_BACKUP_INTENT); if (!NT_SUCCESS (status)) { debug_printf ("NtOpenFile (%S) failed, status = %y", &root, status); goto out; } /* Strip leading backslash */ ++recycler.Buffer; recycler.Length -= sizeof (WCHAR); /* Store length of recycler base dir, if it's necessary to create it. */ recycler_base_len = recycler.Length; /* On NTFS or ReFS the recycler dir contains user specific subdirs, which are the actual recycle bins per user. The name if this dir is the string representation of the user SID. */ if (fs_has_per_user_recycler) { UNICODE_STRING sid; WCHAR sidbuf[128]; /* Unhide trailing backslash. */ recycler.Length += sizeof (WCHAR); RtlInitEmptyUnicodeString (&sid, sidbuf, sizeof sidbuf); RtlConvertSidToUnicodeString (&sid, cygheap->user.sid (), FALSE); RtlAppendUnicodeStringToString (&recycler, &sid); recycler_user_len = recycler.Length; } RtlAppendUnicodeToString (&recycler, L"\\"); } /* Create hopefully unique filename. Since we have to stick to the current directory on remote shares, make the new filename at least very unlikely to match by accident. It starts with ".cyg", with "cyg" transposed into the Unicode low surrogate area starting at U+dc00. Use plain ASCII chars on filesystems not supporting Unicode. The rest of the filename is the inode number in hex encoding and a hash of the full NT path in hex. The combination allows to remove multiple hardlinks to the same file. */ RtlAppendUnicodeToString (&recycler, pc.fs_flags () & FILE_UNICODE_ON_DISK ? L".\xdc63\xdc79\xdc67" : L".cyg"); pfii = (PFILE_INTERNAL_INFORMATION) infobuf; /* Note: Modern Samba versions apparently don't like buffer sizes of more than 65535 in some NtQueryInformationFile/NtSetInformationFile calls. Therefore we better use exact buffer sizes from now on. */ status = NtQueryInformationFile (fh, &io, pfii, sizeof *pfii, FileInternalInformation); if (!NT_SUCCESS (status)) { debug_printf ("NtQueryInformationFile (%S, FileInternalInformation) " "failed, status = %y", pc.get_nt_native_path (), status); goto out; } RtlInt64ToHexUnicodeString (pfii->FileId.QuadPart, &recycler, TRUE); RtlInt64ToHexUnicodeString (hash_path_name (0, pc.get_nt_native_path ()), &recycler, TRUE); /* Shoot. */ pfri = (PFILE_RENAME_INFORMATION) infobuf; pfri->ReplaceIfExists = TRUE; pfri->RootDirectory = pc.isremote () ? NULL : rootdir; pfri->FileNameLength = recycler.Length; memcpy (pfri->FileName, recycler.Buffer, recycler.Length); frisiz = sizeof *pfri + pfri->FileNameLength - sizeof (WCHAR); status = NtSetInformationFile (fh, &io, pfri, frisiz, FileRenameInformation); if (status == STATUS_OBJECT_PATH_NOT_FOUND && !pc.isremote ()) { /* Ok, so the recycler and/or the recycler/SID directory don't exist. First reopen root dir with permission to create subdirs. */ NtClose (rootdir); InitializeObjectAttributes (&attr, &root, OBJ_CASE_INSENSITIVE, NULL, NULL); status = NtOpenFile (&rootdir, FILE_ADD_SUBDIRECTORY, &attr, &io, FILE_SHARE_VALID_FLAGS, FILE_OPEN_FOR_BACKUP_INTENT); if (!NT_SUCCESS (status)) { debug_printf ("NtOpenFile (%S) failed, status = %y", &recycler, status); goto out; } /* Then check if recycler exists by opening and potentially creating it. Yes, we can really do that. Typically the recycle bin is created by the first user actually using the bin. Pre-Vista, the permissions are the default permissions propagated from the root directory. Since Vista the top-level recycle dir has explicit permissions. */ InitializeObjectAttributes (&attr, &recycler, OBJ_CASE_INSENSITIVE, rootdir, wincap.has_recycle_dot_bin () ? recycler_sd (true, true) : NULL); recycler.Length = recycler_base_len; status = NtCreateFile (&recyclerdir, READ_CONTROL | (fs_has_per_user_recycler ? 0 : FILE_ADD_FILE), &attr, &io, NULL, FILE_ATTRIBUTE_DIRECTORY | FILE_ATTRIBUTE_SYSTEM | FILE_ATTRIBUTE_HIDDEN, FILE_SHARE_VALID_FLAGS, FILE_OPEN_IF, FILE_DIRECTORY_FILE, NULL, 0); if (!NT_SUCCESS (status)) { debug_printf ("NtCreateFile (%S) failed, status = %y", &recycler, status); goto out; } /* Next, if necessary, check if the recycler/SID dir exists and create it if not. */ if (fs_has_per_user_recycler) { NtClose (recyclerdir); recycler.Length = recycler_user_len; InitializeObjectAttributes (&attr, &recycler, OBJ_CASE_INSENSITIVE, rootdir, recycler_sd (false, true)); status = NtCreateFile (&recyclerdir, READ_CONTROL | FILE_ADD_FILE, &attr, &io, NULL, FILE_ATTRIBUTE_DIRECTORY | FILE_ATTRIBUTE_SYSTEM | FILE_ATTRIBUTE_HIDDEN, FILE_SHARE_VALID_FLAGS, FILE_OPEN_IF, FILE_DIRECTORY_FILE, NULL, 0); if (!NT_SUCCESS (status)) { debug_printf ("NtCreateFile (%S) failed, status = %y", &recycler, status); goto out; } } /* The desktop.ini and INFO2 (pre-Vista) files are expected by Windows Explorer. Otherwise, the created bin is treated as corrupted */ if (io.Information == FILE_CREATED) { RtlInitUnicodeString (&fname, L"desktop.ini"); InitializeObjectAttributes (&attr, &fname, OBJ_CASE_INSENSITIVE, recyclerdir, recycler_sd (false, false)); status = NtCreateFile (&tmp_fh, FILE_GENERIC_WRITE, &attr, &io, NULL, FILE_ATTRIBUTE_SYSTEM | FILE_ATTRIBUTE_HIDDEN, FILE_SHARE_VALID_FLAGS, FILE_CREATE, FILE_SYNCHRONOUS_IO_NONALERT | FILE_NON_DIRECTORY_FILE, NULL, 0); if (!NT_SUCCESS (status)) debug_printf ("NtCreateFile (%S) failed, status = %y", &recycler, status); else { status = NtWriteFile (tmp_fh, NULL, NULL, NULL, &io, desktop_ini, sizeof desktop_ini - 1, NULL, NULL); if (!NT_SUCCESS (status)) debug_printf ("NtWriteFile (%S) failed, status = %y", &fname, status); else if (wincap.has_recycle_dot_bin ()) { status = NtWriteFile (tmp_fh, NULL, NULL, NULL, &io, desktop_ini_ext, sizeof desktop_ini_ext - 1, NULL, NULL); if (!NT_SUCCESS (status)) debug_printf ("NtWriteFile (%S) failed, status = %y", &fname, status); } NtClose (tmp_fh); } if (!wincap.has_recycle_dot_bin ()) /* No INFO2 file since Vista */ { RtlInitUnicodeString (&fname, L"INFO2"); status = NtCreateFile (&tmp_fh, FILE_GENERIC_WRITE, &attr, &io, NULL, FILE_ATTRIBUTE_ARCHIVE | FILE_ATTRIBUTE_HIDDEN, FILE_SHARE_VALID_FLAGS, FILE_CREATE, FILE_SYNCHRONOUS_IO_NONALERT | FILE_NON_DIRECTORY_FILE, NULL, 0); if (!NT_SUCCESS (status)) debug_printf ("NtCreateFile (%S) failed, status = %y", &recycler, status); else { status = NtWriteFile (tmp_fh, NULL, NULL, NULL, &io, info2, sizeof info2, NULL, NULL); if (!NT_SUCCESS (status)) debug_printf ("NtWriteFile (%S) failed, status = %y", &fname, status); NtClose (tmp_fh); } } } NtClose (recyclerdir); /* Shoot again. */ status = NtSetInformationFile (fh, &io, pfri, frisiz, FileRenameInformation); } if (!NT_SUCCESS (status)) { debug_printf ("Move %S to %S failed, status = %y", pc.get_nt_native_path (), &recycler, status); goto out; } /* Moving to the bin worked. */ bin_stat = has_been_moved; /* Now we try to set the delete disposition. If that worked, we're done. We try this here first, as long as we still have the open handle. Otherwise the below code closes the handle to allow replacing the file. */ status = NtSetInformationFile (fh, &io, &disp, sizeof disp, FileDispositionInformation); if (status == STATUS_DIRECTORY_NOT_EMPTY) { /* Uh oh! This was supposed to be avoided by the check_dir_not_empty test in unlink_nt, but given that the test isn't atomic, this *can* happen. Try to move the dir back ASAP. */ pfri->RootDirectory = NULL; pfri->FileNameLength = pc.get_nt_native_path ()->Length; memcpy (pfri->FileName, pc.get_nt_native_path ()->Buffer, pc.get_nt_native_path ()->Length); frisiz = sizeof *pfri + pfri->FileNameLength - sizeof (WCHAR); if (NT_SUCCESS (NtSetInformationFile (fh, &io, pfri, frisiz, FileRenameInformation))) { /* Give notice to unlink_nt and leave immediately. This avoids closing the handle, which might still be used if called from the rm -r workaround code. */ bin_stat = dir_not_empty; goto out; } } /* In case of success, restore R/O attribute to accommodate hardlinks. That leaves potentially hardlinks around with the R/O bit suddenly off if setting the delete disposition failed, but please, keep in mind this is really a border case only. */ if ((access & FILE_WRITE_ATTRIBUTES) && NT_SUCCESS (status) && !pc.isdir ()) NtSetAttributesFile (fh, pc.file_attributes ()); NtClose (fh); fh = NULL; /* So unlink_nt doesn't close the handle twice. */ /* On success or when trying to unlink a directory we just return here. The below code only works for files. */ if (NT_SUCCESS (status) || pc.isdir ()) goto out; /* The final trick. We create a temporary file with delete-on-close semantic and rename that file to the file just moved to the bin. This typically overwrites the original file and we get rid of it, even if neither setting the delete dispostion, nor setting delete-on-close on the original file succeeds. There are still cases in which this fails, for instance, when trying to delete a hardlink to a DLL used by the unlinking application itself. */ RtlAppendUnicodeToString (&recycler, L"X"); InitializeObjectAttributes (&attr, &recycler, 0, rootdir, NULL); status = NtCreateFile (&tmp_fh, DELETE, &attr, &io, NULL, FILE_ATTRIBUTE_NORMAL, 0, FILE_SUPERSEDE, FILE_NON_DIRECTORY_FILE | FILE_DELETE_ON_CLOSE, NULL, 0); if (!NT_SUCCESS (status)) { debug_printf ("Creating file for overwriting failed, status = %y", status); goto out; } status = NtSetInformationFile (tmp_fh, &io, pfri, frisiz, FileRenameInformation); NtClose (tmp_fh); if (!NT_SUCCESS (status)) debug_printf ("Overwriting with another file failed, status = %y", status); out: if (rootdir) NtClose (rootdir); debug_printf ("%S, return bin_status %d", pc.get_nt_native_path (), bin_stat); return bin_stat; } static NTSTATUS check_dir_not_empty (HANDLE dir, path_conv &pc) { IO_STATUS_BLOCK io; const ULONG bufsiz = 3 * sizeof (FILE_NAMES_INFORMATION) + 3 * NAME_MAX * sizeof (WCHAR); PFILE_NAMES_INFORMATION pfni = (PFILE_NAMES_INFORMATION) alloca (bufsiz); NTSTATUS status = NtQueryDirectoryFile (dir, NULL, NULL, 0, &io, pfni, bufsiz, FileNamesInformation, FALSE, NULL, TRUE); if (!NT_SUCCESS (status)) { debug_printf ("Checking if directory %S is empty failed, status = %y", pc.get_nt_native_path (), status); return status; } int cnt = 1; do { while (pfni->NextEntryOffset) { if (++cnt > 2) { UNICODE_STRING fname; OBJECT_ATTRIBUTES attr; FILE_BASIC_INFORMATION fbi; pfni = (PFILE_NAMES_INFORMATION) ((caddr_t) pfni + pfni->NextEntryOffset); RtlInitCountedUnicodeString(&fname, pfni->FileName, pfni->FileNameLength); InitializeObjectAttributes (&attr, &fname, 0, dir, NULL); status = NtQueryAttributesFile (&attr, &fbi); /* Intensive testing shows that sometimes directories, for which the delete disposition has already been set, and the deleting handle is already closed, can linger in the parent dir for a couple of ms for no apparent reason (Windows Defender or other real-time scanners are suspect). A fast rm -r is capable to exploit this problem. Setting the delete disposition of the parent dir then fails with STATUS_DIRECTORY_NOT_EMPTY. Examining the content of the affected dir can then show either that the dir is empty, or it can contain a lingering subdir. Calling NtQueryAttributesFile on that subdir returns with STATUS_DELETE_PENDING, or it disappeared before that call. That's what we do here. If NtQueryAttributesFile succeeded, or if the error code does not indicate an already deleted entry, STATUS_DIRECTORY_NOT_EMPTY is returned. Otherwise STATUS_SUCCESS is returned. Read on in unlink_nt. */ if (status != STATUS_DELETE_PENDING && status != STATUS_OBJECT_NAME_NOT_FOUND && status != STATUS_OBJECT_PATH_NOT_FOUND) { debug_printf ("Directory %S not empty, found file <%S>, " "query status = %y", pc.get_nt_native_path (), &fname, status); return STATUS_DIRECTORY_NOT_EMPTY; } } pfni = (PFILE_NAMES_INFORMATION) ((caddr_t) pfni + pfni->NextEntryOffset); } } while (NT_SUCCESS (NtQueryDirectoryFile (dir, NULL, NULL, 0, &io, pfni, bufsiz, FileNamesInformation, FALSE, NULL, FALSE))); return STATUS_SUCCESS; } NTSTATUS unlink_nt (path_conv &pc) { NTSTATUS status; HANDLE fh, fh_ro = NULL; OBJECT_ATTRIBUTES attr; IO_STATUS_BLOCK io; HANDLE old_trans = NULL, trans = NULL; ULONG num_links = 1; FILE_DISPOSITION_INFORMATION disp = { TRUE }; int reopened = 0; bin_status bin_stat = dont_move; syscall_printf ("Trying to delete %S, isdir = %d", pc.get_nt_native_path (), pc.isdir ()); ACCESS_MASK access = DELETE; ULONG flags = FILE_OPEN_FOR_BACKUP_INTENT; /* Add the reparse point flag to native symlinks, otherwise we remove the target, not the symlink. */ if (pc.is_rep_symlink ()) flags |= FILE_OPEN_REPARSE_POINT; pc.get_object_attr (attr, sec_none_nih); /* If the R/O attribute is set, we have to open the file with FILE_WRITE_ATTRIBUTES to be able to remove this flags before trying to delete it. We do this separately because there are filesystems out there (MVFS), which refuse a request to open a file for DELETE if the DOS R/O attribute is set for the file. After removing the R/O attribute, just re-open the file for DELETE and go ahead. */ if (pc.file_attributes () & FILE_ATTRIBUTE_READONLY) { FILE_STANDARD_INFORMATION fsi; /* If possible, hide the non-atomicity of the "remove R/O flag, remove link to file" operation behind a transaction. */ if (wincap.has_transactions () && (pc.fs_flags () & FILE_SUPPORTS_TRANSACTIONS)) start_transaction (old_trans, trans); retry_open: status = NtOpenFile (&fh_ro, FILE_WRITE_ATTRIBUTES, &attr, &io, FILE_SHARE_VALID_FLAGS, flags); if (NT_SUCCESS (status)) { debug_printf ("Opening %S for removing R/O succeeded", pc.get_nt_native_path ()); NTSTATUS status2 = NtSetAttributesFile (fh_ro, pc.file_attributes () & ~FILE_ATTRIBUTE_READONLY); if (!NT_SUCCESS (status2)) debug_printf ("Removing R/O on %S failed, status = %y", pc.get_nt_native_path (), status2); pc.init_reopen_attr (attr, fh_ro); } else { debug_printf ("Opening %S for removing R/O failed, status = %y", pc.get_nt_native_path (), status); if (NT_TRANSACTIONAL_ERROR (status) && trans) { /* If NtOpenFile fails due to transactional problems, stop transaction and go ahead without. */ stop_transaction (status, old_trans, trans); debug_printf ("Transaction failure. Retry open."); goto retry_open; } } if (pc.is_lnk_symlink ()) { status = NtQueryInformationFile (fh_ro, &io, &fsi, sizeof fsi, FileStandardInformation); if (NT_SUCCESS (status)) num_links = fsi.NumberOfLinks; } access |= FILE_WRITE_ATTRIBUTES; } /* First try to open the file with only allowing sharing for delete. If the file has an open handle on it, other than just for deletion, this will fail. That indicates that the file has to be moved to the recycle bin so that it actually disappears from its directory even though its in use. Otherwise, if opening doesn't fail, the file is not in use and we can go straight to setting the delete disposition flag. NOTE: The missing sharing modes FILE_SHARE_READ and FILE_SHARE_WRITE do NOT result in a STATUS_SHARING_VIOLATION, if another handle is opened for reading/writing metadata only. In other words, if another handle is open, but does not have the file open with FILE_READ_DATA or FILE_WRITE_DATA, the following NtOpenFile call will succeed. So, apparently there is no reliable way to find out if a file is already open elsewhere for other purposes than reading and writing data. */ status = NtOpenFile (&fh, access, &attr, &io, FILE_SHARE_DELETE, flags); /* STATUS_SHARING_VIOLATION is what we expect. STATUS_LOCK_NOT_GRANTED can be generated under not quite clear circumstances when trying to open a file on NFS with FILE_SHARE_DELETE only. This has been observed with SFU 3.5 if the NFS share has been mounted under a drive letter. It's not generated for all files, but only for some. If it's generated once for a file, it will be generated all the time. It looks as if wrong file state information is stored within the NFS client which never times out. Opening the file with FILE_SHARE_VALID_FLAGS will work, though, and it is then possible to delete the file quite normally. */ if (status == STATUS_SHARING_VIOLATION || status == STATUS_LOCK_NOT_GRANTED) { debug_printf ("Sharing violation when opening %S", pc.get_nt_native_path ()); /* We never call try_to_bin on NFS and NetApp for the follwing reasons: NFS implements its own mechanism to remove in-use files, which looks quite similar to what we do in try_to_bin for remote files. Netapp filesystems don't understand the "move and delete" method at all and have all kinds of weird effects. Just setting the delete dispositon usually works fine, though. */ if (!pc.fs_is_nfs () && !pc.fs_is_netapp ()) bin_stat = move_to_bin; /* If the file is not a directory, of if we didn't set the move_to_bin flag, just proceed with the FILE_SHARE_VALID_FLAGS set. */ if (!pc.isdir () || bin_stat == dont_move) status = NtOpenFile (&fh, access, &attr, &io, FILE_SHARE_VALID_FLAGS, flags); else { /* Otherwise it's getting tricky. The directory is opened in some process, so we're supposed to move it to the recycler and mark it for deletion. But what if the directory is not empty? The move will work, but the subsequent delete will fail. So we would have to move it back. While we do that in try_to_bin, it's bad, because the move results in a temporary inconsistent state. So, we test first if the directory is empty. If not, we bail out with STATUS_DIRECTORY_NOT_EMPTY. This avoids most of the problems. */ status = NtOpenFile (&fh, access | FILE_LIST_DIRECTORY | SYNCHRONIZE, &attr, &io, FILE_SHARE_VALID_FLAGS, flags | FILE_SYNCHRONOUS_IO_NONALERT); if (NT_SUCCESS (status)) { status = check_dir_not_empty (fh, pc); if (!NT_SUCCESS (status)) { NtClose (fh); if (fh_ro) NtClose (fh_ro); goto out; } } } } if (fh_ro) NtClose (fh_ro); if (!NT_SUCCESS (status)) { if (status == STATUS_DELETE_PENDING) { debug_printf ("Delete %S already pending", pc.get_nt_native_path ()); status = STATUS_SUCCESS; goto out; } debug_printf ("Opening %S for delete failed, status = %y", pc.get_nt_native_path (), status); goto out; } /* Try to move to bin if a sharing violation occured. If that worked, we're done. */ if (bin_stat == move_to_bin && (bin_stat = try_to_bin (pc, fh, access, flags)) >= has_been_moved) { if (bin_stat == has_been_moved) status = STATUS_SUCCESS; else { status = STATUS_DIRECTORY_NOT_EMPTY; NtClose (fh); } goto out; } try_again: /* Try to set delete disposition. */ status = NtSetInformationFile (fh, &io, &disp, sizeof disp, FileDispositionInformation); if (!NT_SUCCESS (status)) { debug_printf ("Setting delete disposition on %S failed, status = %y", pc.get_nt_native_path (), status); if (status == STATUS_DIRECTORY_NOT_EMPTY) { NTSTATUS status2 = STATUS_SUCCESS; if (!reopened) { /* Have to close and reopen the file from scratch, otherwise we collide with the delete-only sharing mode. */ pc.get_object_attr (attr, sec_none_nih); NtClose (fh); status2 = NtOpenFile (&fh, access | FILE_LIST_DIRECTORY | SYNCHRONIZE, &attr, &io, FILE_SHARE_VALID_FLAGS, flags | FILE_SYNCHRONOUS_IO_NONALERT); } if (NT_SUCCESS (status2) && reopened < 20) { /* Workaround rm -r problem: Sometimes a deleted directory lingers in its parent dir after the deleting handle has already been closed. This can break deleting the parent dir. See the comment in check_dir_not_empty for more information. What we do here is this: If check_dir_not_empty returns STATUS_SUCCESS, the dir is either empty, or only inhabited by already deleted entries. If so, we try to move the dir into the bin. This usually works. However, if we're on a filesystem which doesn't support the try_to_bin method, or if moving to the bin doesn't work for some reason, just try to delete the directory again, with a very short grace period to free the CPU for a while. This gives the OS time to clean up. 5ms is enough in my testing to make sure that we don't have to try more than once in practically all cases. While this is an extrem bordercase, we don't want to hang infinitely in case a file in the directory is in the "delete pending" state but an application holds an open handle to it for a longer time. So we don't try this more than 20 times, which means a process time of 100-120ms. */ if (check_dir_not_empty (fh, pc) == STATUS_SUCCESS) { if (bin_stat == dont_move) { bin_stat = move_to_bin; if (!pc.fs_is_nfs () && !pc.fs_is_netapp ()) { debug_printf ("Try-to-bin %S", pc.get_nt_native_path ()); bin_stat = try_to_bin (pc, fh, access, flags); } } /* Do NOT handle bin_stat == dir_not_empty here! */ if (bin_stat == has_been_moved) status = STATUS_SUCCESS; else { debug_printf ("Try %S again", pc.get_nt_native_path ()); ++reopened; Sleep (5L); goto try_again; } } } else if (status2 != STATUS_OBJECT_PATH_NOT_FOUND && status2 != STATUS_OBJECT_NAME_NOT_FOUND) { fh = NULL; debug_printf ("Opening dir %S for check_dir_not_empty failed, " "status = %y", pc.get_nt_native_path (), status2); } else /* Directory disappeared between NtClose and NtOpenFile. */ status = STATUS_SUCCESS; } /* Trying to delete a hardlink to a file in use by the system in some way (for instance, font files) by setting the delete disposition fails with STATUS_CANNOT_DELETE. Strange enough, deleting these hardlinks using delete-on-close semantic works... most of the time. Don't use delete-on-close on remote shares. If two processes have open handles on a file and one of them calls unlink, the file is removed from the remote share even though the other process still has an open handle. That process than gets Win32 error 59, ERROR_UNEXP_NET_ERR when trying to access the file. Microsoft KB 837665 describes this problem as a bug in 2K3, but I have reproduced it on other systems. */ else if (status == STATUS_CANNOT_DELETE && (!pc.isremote () || pc.fs_is_ncfsd ())) { HANDLE fh2; debug_printf ("Cannot delete %S, try delete-on-close", pc.get_nt_native_path ()); /* Re-open from handle so we open the correct file no matter if it has been moved to the bin or not. */ status = NtOpenFile (&fh2, DELETE, pc.init_reopen_attr (attr, fh), &io, bin_stat == move_to_bin ? FILE_SHARE_VALID_FLAGS : FILE_SHARE_DELETE, flags | FILE_DELETE_ON_CLOSE); if (!NT_SUCCESS (status)) { debug_printf ("Setting delete-on-close on %S failed, status = %y", pc.get_nt_native_path (), status); /* This is really the last chance. If it hasn't been moved to the bin already, try it now. If moving to the bin succeeds, we got rid of the file in some way, even if unlinking didn't work. */ if (bin_stat == dont_move) bin_stat = try_to_bin (pc, fh, access, flags); if (bin_stat >= has_been_moved) status = bin_stat == has_been_moved ? STATUS_SUCCESS : STATUS_DIRECTORY_NOT_EMPTY; } else NtClose (fh2); } } if (fh) { if (access & FILE_WRITE_ATTRIBUTES) { /* Restore R/O attribute if setting the delete disposition failed. */ if (!NT_SUCCESS (status)) NtSetAttributesFile (fh, pc.file_attributes ()); /* If we succeeded, restore R/O attribute to accommodate hardlinks. Only ever try to do this for our own winsymlinks, because there's a problem with setting the delete disposition: http://msdn.microsoft.com/en-us/library/ff545765%28VS.85%29.aspx "Subsequently, the only legal operation by such a caller is to close the open file handle." FIXME? On Vista and later, we could use FILE_HARD_LINK_INFORMATION to find all hardlinks and use one of them to restore the R/O bit, after the NtClose, but before we stop the transaction. This avoids the aforementioned problem entirely . */ else if (pc.is_lnk_symlink () && num_links > 1) NtSetAttributesFile (fh, pc.file_attributes ()); } NtClose (fh); } out: /* Stop transaction if we started one. */ if (trans) stop_transaction (status, old_trans, trans); syscall_printf ("%S, return status = %y", pc.get_nt_native_path (), status); return status; } extern "C" int unlink (const char *ourname) { int res = -1; dev_t devn; NTSTATUS status; path_conv win32_name (ourname, PC_SYM_NOFOLLOW, stat_suffixes); if (win32_name.error) { set_errno (win32_name.error); goto done; } devn = win32_name.get_device (); if (isproc_dev (devn)) { set_errno (EROFS); goto done; } if (!win32_name.exists ()) { debug_printf ("unlinking a nonexistent file"); set_errno (ENOENT); goto done; } else if (win32_name.isdir ()) { debug_printf ("unlinking a directory"); set_errno (EPERM); goto done; } status = unlink_nt (win32_name); if (NT_SUCCESS (status)) res = 0; else __seterrno_from_nt_status (status); done: syscall_printf ("%R = unlink(%s)", res, ourname); return res; } extern "C" int _remove_r (struct _reent *, const char *ourname) { path_conv win32_name (ourname, PC_SYM_NOFOLLOW); if (win32_name.error) { set_errno (win32_name.error); syscall_printf ("%R = remove(%s)",-1, ourname); return -1; } return win32_name.isdir () ? rmdir (ourname) : unlink (ourname); } extern "C" int remove (const char *ourname) { path_conv win32_name (ourname, PC_SYM_NOFOLLOW); if (win32_name.error) { set_errno (win32_name.error); syscall_printf ("-1 = remove (%s)", ourname); return -1; } int res = win32_name.isdir () ? rmdir (ourname) : unlink (ourname); syscall_printf ("%R = remove(%s)", res, ourname); return res; } extern "C" pid_t getpid () { syscall_printf ("%d = getpid()", myself->pid); return myself->pid; } extern "C" pid_t _getpid_r (struct _reent *) { return getpid (); } /* getppid: POSIX 4.1.1.1 */ extern "C" pid_t getppid () { syscall_printf ("%d = getppid()", myself->ppid); return myself->ppid; } /* setsid: POSIX 4.3.2.1 */ extern "C" pid_t setsid (void) { #ifdef NEWVFORK vfork_save *vf = vfork_storage.val (); /* This is a horrible, horrible kludge */ if (vf && vf->pid < 0) { pid_t pid = fork (); if (pid > 0) { syscall_printf ("longjmping due to vfork"); vf->restore_pid (pid); } /* assuming that fork was successful */ } #endif if (myself->pgid == myself->pid) syscall_printf ("hmm. pgid %d pid %d", myself->pgid, myself->pid); else { myself->ctty = -2; myself->sid = myself->pid; myself->pgid = myself->pid; if (cygheap->ctty) cygheap->close_ctty (); syscall_printf ("sid %d, pgid %d, %s", myself->sid, myself->pgid, myctty ()); return myself->sid; } set_errno (EPERM); return -1; } extern "C" pid_t getsid (pid_t pid) { pid_t res; if (!pid) res = myself->sid; else { pinfo p (pid); if (p) res = p->sid; else { set_errno (ESRCH); res = -1; } } syscall_printf ("%R = getsid(%d)", pid); return res; } extern "C" ssize_t read (int fd, void *ptr, size_t len) { size_t res = (size_t) -1; pthread_testcancel (); __try { cygheap_fdget cfd (fd); if (cfd < 0) __leave; if ((cfd->get_flags () & O_ACCMODE) == O_WRONLY) { set_errno (EBADF); __leave; } /* Could block, so let user know we at least got here. */ syscall_printf ("read(%d, %p, %d) %sblocking", fd, ptr, len, cfd->is_nonblocking () ? "non" : ""); cfd->read (ptr, len); res = len; } __except (EFAULT) {} __endtry syscall_printf ("%lR = read(%d, %p, %d)", res, fd, ptr, len); MALLOC_CHECK; return (ssize_t) res; } EXPORT_ALIAS (read, _read) extern "C" ssize_t readv (int fd, const struct iovec *const iov, const int iovcnt) { ssize_t res = -1; pthread_testcancel (); __try { const ssize_t tot = check_iovec_for_read (iov, iovcnt); cygheap_fdget cfd (fd); if (cfd < 0) __leave; if (tot <= 0) { res = tot; __leave; } if ((cfd->get_flags () & O_ACCMODE) == O_WRONLY) { set_errno (EBADF); __leave; } /* Could block, so let user know we at least got here. */ syscall_printf ("readv(%d, %p, %d) %sblocking", fd, iov, iovcnt, cfd->is_nonblocking () ? "non" : ""); res = cfd->readv (iov, iovcnt, tot); } __except (EFAULT) {} __endtry syscall_printf ("%lR = readv(%d, %p, %d)", res, fd, iov, iovcnt); MALLOC_CHECK; return res; } extern "C" ssize_t pread (int fd, void *ptr, size_t len, off_t off) { ssize_t res; pthread_testcancel (); cygheap_fdget cfd (fd); if (cfd < 0) res = -1; else res = cfd->pread (ptr, len, off); syscall_printf ("%lR = pread(%d, %p, %d, %d)", res, fd, ptr, len, off); return res; } extern "C" ssize_t write (int fd, const void *ptr, size_t len) { ssize_t res = -1; pthread_testcancel (); __try { cygheap_fdget cfd (fd); if (cfd < 0) __leave; if ((cfd->get_flags () & O_ACCMODE) == O_RDONLY) { set_errno (EBADF); __leave; } /* Could block, so let user know we at least got here. */ if (fd == 1 || fd == 2) paranoid_printf ("write(%d, %p, %d)", fd, ptr, len); else syscall_printf ("write(%d, %p, %d)", fd, ptr, len); res = cfd->write (ptr, len); } __except (EFAULT) {} __endtry syscall_printf ("%lR = write(%d, %p, %d)", res, fd, ptr, len); MALLOC_CHECK; return res; } EXPORT_ALIAS (write, _write) extern "C" ssize_t writev (const int fd, const struct iovec *const iov, const int iovcnt) { ssize_t res = -1; pthread_testcancel (); __try { const ssize_t tot = check_iovec_for_write (iov, iovcnt); cygheap_fdget cfd (fd); if (cfd < 0) __leave; if (tot <= 0) { res = tot; __leave; } if ((cfd->get_flags () & O_ACCMODE) == O_RDONLY) { set_errno (EBADF); __leave; } /* Could block, so let user know we at least got here. */ if (fd == 1 || fd == 2) paranoid_printf ("writev(%d, %p, %d)", fd, iov, iovcnt); else syscall_printf ("writev(%d, %p, %d)", fd, iov, iovcnt); res = cfd->writev (iov, iovcnt, tot); } __except (EFAULT) {} __endtry if (fd == 1 || fd == 2) paranoid_printf ("%lR = writev(%d, %p, %d)", res, fd, iov, iovcnt); else syscall_printf ("%lR = writev(%d, %p, %d)", res, fd, iov, iovcnt); MALLOC_CHECK; return res; } extern "C" ssize_t pwrite (int fd, void *ptr, size_t len, off_t off) { pthread_testcancel (); ssize_t res; cygheap_fdget cfd (fd); if (cfd < 0) res = -1; else res = cfd->pwrite (ptr, len, off); syscall_printf ("%lR = pwrite(%d, %p, %d, %d)", res, fd, ptr, len, off); return res; } /* _open */ /* newlib's fcntl.h defines _open as taking variable args so we must correspond. The third arg if it exists is: mode_t mode. */ extern "C" int open (const char *unix_path, int flags, ...) { int res = -1; va_list ap; mode_t mode = 0; pthread_testcancel (); __try { syscall_printf ("open(%s, %y)", unix_path, flags); if (!*unix_path) set_errno (ENOENT); else { /* check for optional mode argument */ va_start (ap, flags); mode = va_arg (ap, mode_t); va_end (ap); fhandler_base *fh; cygheap_fdnew fd; if (fd >= 0) { /* This is a temporary kludge until all utilities can catch up with a change in behavior that implements linux functionality: opening a tty should not automatically cause it to become the controlling tty for the process. */ int opt = PC_OPEN | ((flags & (O_NOFOLLOW | O_EXCL)) ? PC_SYM_NOFOLLOW : PC_SYM_FOLLOW); if (!(flags & O_NOCTTY) && fd > 2 && myself->ctty != -2) { flags |= O_NOCTTY; /* flag that, if opened, this fhandler could later be capable of being a controlling terminal if /dev/tty is opened. */ opt |= PC_CTTY; } if (!(fh = build_fh_name (unix_path, opt, stat_suffixes))) ; // errno already set else if ((flags & O_NOFOLLOW) && fh->issymlink ()) { delete fh; set_errno (ELOOP); } else if ((flags & O_DIRECTORY) && fh->exists () && !fh->pc.isdir ()) { delete fh; set_errno (ENOTDIR); } else if (((flags & (O_CREAT | O_EXCL)) == (O_CREAT | O_EXCL)) && fh->exists ()) { delete fh; set_errno (EEXIST); } else if ((fh->is_fs_special () && fh->device_access_denied (flags)) || !fh->open_with_arch (flags, (mode & 07777) & ~cygheap->umask)) delete fh; else { fd = fh; if (fd <= 2) set_std_handle (fd); res = fd; } } } syscall_printf ("%R = open(%s, %y)", res, unix_path, flags); } __except (EFAULT) {} __endtry return res; } EXPORT_ALIAS (open, _open ) EXPORT_ALIAS (open, _open64 ) extern "C" off_t lseek64 (int fd, off_t pos, int dir) { off_t res; if (dir != SEEK_SET && dir != SEEK_CUR && dir != SEEK_END) { set_errno (EINVAL); res = -1; } else { cygheap_fdget cfd (fd); if (cfd >= 0) res = cfd->lseek (pos, dir); else res = -1; } /* Can't use %R/%lR here since res is always 8 bytes */ syscall_printf (res == -1 ? "%D = lseek(%d, %D, %d), errno %d" : "%D = lseek(%d, %D, %d)", res, fd, pos, dir, get_errno ()); return res; } EXPORT_ALIAS (lseek64, _lseek64) #ifdef __x86_64__ EXPORT_ALIAS (lseek64, lseek) EXPORT_ALIAS (lseek64, _lseek) #else extern "C" _off_t lseek (int fd, _off_t pos, int dir) { return lseek64 (fd, (off_t) pos, dir); } EXPORT_ALIAS (lseek, _lseek) #endif extern "C" int close (int fd) { int res; syscall_printf ("close(%d)", fd); pthread_testcancel (); MALLOC_CHECK; cygheap_fdget cfd (fd, true); if (cfd < 0) res = -1; else { cfd->isclosed (true); res = cfd->close_with_arch (); cfd.release (); } syscall_printf ("%R = close(%d)", res, fd); MALLOC_CHECK; return res; } EXPORT_ALIAS (close, _close) extern "C" int isatty (int fd) { int res; cygheap_fdget cfd (fd); if (cfd < 0) res = 0; else res = cfd->is_tty (); syscall_printf ("%R = isatty(%d)", res, fd); return res; } EXPORT_ALIAS (isatty, _isatty) extern "C" int link (const char *oldpath, const char *newpath) { int res = -1; fhandler_base *fh; if (!(fh = build_fh_name (oldpath, PC_SYM_NOFOLLOW | PC_KEEP_HANDLE, stat_suffixes))) goto error; if (fh->error ()) { debug_printf ("got %d error from build_fh_name", fh->error ()); set_errno (fh->error ()); } else if (fh->pc.isdir ()) set_errno (EPERM); /* We do not permit linking directories. */ else if (!fh->pc.exists ()) set_errno (ENOENT); else res = fh->link (newpath); delete fh; error: syscall_printf ("%R = link(%s, %s)", res, oldpath, newpath); return res; } /* chown: POSIX 5.6.5.1 */ /* * chown () is only implemented for Windows NT. Under other operating * systems, it is only a stub that always returns zero. */ static int chown_worker (const char *name, unsigned fmode, uid_t uid, gid_t gid) { int res = -1; fhandler_base *fh; if (!(fh = build_fh_name (name, fmode, stat_suffixes))) goto error; if (fh->error ()) { debug_printf ("got %d error from build_fh_name", fh->error ()); set_errno (fh->error ()); } else res = fh->fchown (uid, gid); delete fh; error: syscall_printf ("%R = %schown(%s,...)", res, (fmode & PC_SYM_NOFOLLOW) ? "l" : "", name); return res; } extern "C" int chown32 (const char * name, uid_t uid, gid_t gid) { return chown_worker (name, PC_SYM_FOLLOW, uid, gid); } #ifdef __x86_64__ EXPORT_ALIAS (chown32, chown) #else extern "C" int chown (const char * name, __uid16_t uid, __gid16_t gid) { return chown_worker (name, PC_SYM_FOLLOW, uid16touid32 (uid), gid16togid32 (gid)); } #endif extern "C" int lchown32 (const char * name, uid_t uid, gid_t gid) { return chown_worker (name, PC_SYM_NOFOLLOW, uid, gid); } #ifdef __x86_64__ EXPORT_ALIAS (lchown32, lchown) #else extern "C" int lchown (const char * name, __uid16_t uid, __gid16_t gid) { return chown_worker (name, PC_SYM_NOFOLLOW, uid16touid32 (uid), gid16togid32 (gid)); } #endif extern "C" int fchown32 (int fd, uid_t uid, gid_t gid) { cygheap_fdget cfd (fd); if (cfd < 0) { syscall_printf ("-1 = fchown (%d,...)", fd); return -1; } int res = cfd->fchown (uid, gid); syscall_printf ("%R = fchown(%s,...)", res, cfd->get_name ()); return res; } #ifdef __x86_64__ EXPORT_ALIAS (fchown32, fchown) #else extern "C" int fchown (int fd, __uid16_t uid, __gid16_t gid) { return fchown32 (fd, uid16touid32 (uid), gid16togid32 (gid)); } #endif /* umask: POSIX 5.3.3.1 */ extern "C" mode_t umask (mode_t mask) { mode_t oldmask; oldmask = cygheap->umask; cygheap->umask = mask & 0777; return oldmask; } int chmod_device (path_conv& pc, mode_t mode) { return mknod_worker (pc.get_win32 (), pc.dev.mode & S_IFMT, mode, pc.dev.get_major (), pc.dev.get_minor ()); } #define FILTERED_MODE(m) ((m) & (S_ISUID | S_ISGID | S_ISVTX \ | S_IRWXU | S_IRWXG | S_IRWXO)) /* chmod: POSIX 5.6.4.1 */ extern "C" int chmod (const char *path, mode_t mode) { int res = -1; fhandler_base *fh; if (!(fh = build_fh_name (path, PC_SYM_FOLLOW, stat_suffixes))) goto error; if (fh->error ()) { debug_printf ("got %d error from build_fh_name", fh->error ()); set_errno (fh->error ()); } else res = fh->fchmod (FILTERED_MODE (mode)); delete fh; error: syscall_printf ("%R = chmod(%s, 0%o)", res, path, mode); return res; } /* fchmod: P96 5.6.4.1 */ extern "C" int fchmod (int fd, mode_t mode) { cygheap_fdget cfd (fd); if (cfd < 0) { syscall_printf ("-1 = fchmod (%d, 0%o)", fd, mode); return -1; } return cfd->fchmod (FILTERED_MODE (mode)); } #ifndef __x86_64__ static void stat64_to_stat32 (struct stat *src, struct __stat32 *dst) { dst->st_dev = ((src->st_dev >> 8) & 0xff00) | (src->st_dev & 0xff); dst->st_ino = ((unsigned) (src->st_ino >> 32)) | (unsigned) src->st_ino; dst->st_mode = src->st_mode; dst->st_nlink = src->st_nlink; dst->st_uid = src->st_uid; dst->st_gid = src->st_gid; dst->st_rdev = ((src->st_rdev >> 8) & 0xff00) | (src->st_rdev & 0xff); dst->st_size = src->st_size; dst->st_atim = src->st_atim; dst->st_mtim = src->st_mtim; dst->st_ctim = src->st_ctim; dst->st_blksize = src->st_blksize; dst->st_blocks = src->st_blocks; } #endif static struct stat dev_st; static bool dev_st_inited; void fhandler_base::stat_fixup (struct stat *buf) { /* For devices, set inode number to device number. This gives us a valid, unique inode number without having to call hash_path_name. */ if (!buf->st_ino) buf->st_ino = (get_major () == DEV_VIRTFS_MAJOR) ? get_ino () : get_device (); /* For /dev-based devices, st_dev must be set to the device number of /dev, not it's own device major/minor numbers. What we do here to speed up the process is to fetch the device number of /dev only once, liberally assuming that /dev doesn't change over the lifetime of a process. */ if (!buf->st_dev) { if (dev ().is_dev_resident ()) { if (!dev_st_inited) { stat64 ("/dev", &dev_st); dev_st_inited = true; } buf->st_dev = dev_st.st_dev; } else buf->st_dev = get_device (); } /* Only set st_rdev if it's a device. */ if (!buf->st_rdev && get_major () != DEV_VIRTFS_MAJOR) { buf->st_rdev = get_device (); /* consX, console, conin, and conout point to the same device. Make sure the link count is correct. */ if (buf->st_rdev == (dev_t) myself->ctty && iscons_dev (myself->ctty)) buf->st_nlink = 4; /* CD-ROM drives have two links, /dev/srX and /dev/scdX. */ else if (gnu_dev_major (buf->st_rdev) == DEV_CDROM_MAJOR) buf->st_nlink = 2; } } extern "C" int fstat64 (int fd, struct stat *buf) { int res; cygheap_fdget cfd (fd); if (cfd < 0) res = -1; else { memset (buf, 0, sizeof (struct stat)); res = cfd->fstat (buf); if (!res) cfd->stat_fixup (buf); } syscall_printf ("%R = fstat(%d, %p)", res, fd, buf); return res; } extern "C" int _fstat64_r (struct _reent *ptr, int fd, struct stat *buf) { int ret; if ((ret = fstat64 (fd, buf)) == -1) ptr->_errno = get_errno (); return ret; } #ifdef __x86_64__ EXPORT_ALIAS (fstat64, fstat) EXPORT_ALIAS (_fstat64_r, _fstat_r) #else extern "C" int fstat (int fd, struct stat *buf) { struct stat buf64; int ret = fstat64 (fd, &buf64); if (!ret) stat64_to_stat32 (&buf64, (struct __stat32 *) buf); return ret; } extern "C" int _fstat_r (struct _reent *ptr, int fd, struct stat *buf) { int ret; if ((ret = fstat (fd, buf)) == -1) ptr->_errno = get_errno (); return ret; } #endif /* fsync: P96 6.6.1.1 */ extern "C" int fsync (int fd) { pthread_testcancel (); cygheap_fdget cfd (fd); if (cfd < 0) { syscall_printf ("-1 = fsync (%d)", fd); return -1; } return cfd->fsync (); } EXPORT_ALIAS (fsync, fdatasync) static void sync_worker (HANDLE dir, USHORT len, LPCWSTR vol) { NTSTATUS status; HANDLE fh; IO_STATUS_BLOCK io; OBJECT_ATTRIBUTES attr; UNICODE_STRING uvol = { len, len, (WCHAR *) vol }; InitializeObjectAttributes (&attr, &uvol, OBJ_CASE_INSENSITIVE, dir, NULL); status = NtOpenFile (&fh, GENERIC_WRITE, &attr, &io, FILE_SHARE_VALID_FLAGS, 0); if (!NT_SUCCESS (status)) debug_printf ("NtOpenFile (%S), status %y", &uvol, status); else { status = NtFlushBuffersFile (fh, &io); if (!NT_SUCCESS (status)) debug_printf ("NtFlushBuffersFile (%S), status %y", &uvol, status); NtClose (fh); } } /* sync: SUSv3 */ extern "C" void sync () { OBJECT_ATTRIBUTES attr; NTSTATUS status; HANDLE devhdl; UNICODE_STRING device; /* Open \Device object directory. */ RtlInitUnicodeString (&device, L"\\Device"); InitializeObjectAttributes (&attr, &device, OBJ_CASE_INSENSITIVE, NULL, NULL); status = NtOpenDirectoryObject (&devhdl, DIRECTORY_QUERY, &attr); if (!NT_SUCCESS (status)) { debug_printf ("NtOpenDirectoryObject, status %y", status); return; } /* Traverse \Device directory ... */ PDIRECTORY_BASIC_INFORMATION dbi = (PDIRECTORY_BASIC_INFORMATION) alloca (640); BOOLEAN restart = TRUE; ULONG context = 0; while (NT_SUCCESS (NtQueryDirectoryObject (devhdl, dbi, 640, TRUE, restart, &context, NULL))) { restart = FALSE; /* ... and call sync_worker for each HarddiskVolumeX entry. */ if (dbi->ObjectName.Length >= 15 * sizeof (WCHAR) && !wcsncasecmp (dbi->ObjectName.Buffer, L"HarddiskVolume", 14) && iswdigit (dbi->ObjectName.Buffer[14])) sync_worker (devhdl, dbi->ObjectName.Length, dbi->ObjectName.Buffer); } NtClose (devhdl); } /* Cygwin internal */ int __reg2 stat_worker (path_conv &pc, struct stat *buf) { int res = -1; __try { if (pc.error) { debug_printf ("got %d error from path_conv", pc.error); set_errno (pc.error); } else if (pc.exists ()) { fhandler_base *fh; if (!(fh = build_fh_pc (pc))) __leave; debug_printf ("(%S, %p, %p), file_attributes %d", pc.get_nt_native_path (), buf, fh, (DWORD) *fh); memset (buf, 0, sizeof (*buf)); res = fh->fstat (buf); if (!res) fh->stat_fixup (buf); delete fh; } else set_errno (ENOENT); } __except (EFAULT) {} __endtry MALLOC_CHECK; syscall_printf ("%d = (%S,%p)", res, pc.get_nt_native_path (), buf); return res; } extern "C" int stat64 (const char *__restrict name, struct stat *__restrict buf) { syscall_printf ("entering"); path_conv pc (name, PC_SYM_FOLLOW | PC_POSIX | PC_KEEP_HANDLE, stat_suffixes); return stat_worker (pc, buf); } extern "C" int _stat64_r (struct _reent *__restrict ptr, const char *__restrict name, struct stat *buf) { int ret; if ((ret = stat64 (name, buf)) == -1) ptr->_errno = get_errno (); return ret; } #ifdef __x86_64__ EXPORT_ALIAS (stat64, stat) EXPORT_ALIAS (_stat64_r, _stat_r) #else extern "C" int stat (const char *__restrict name, struct stat *__restrict buf) { struct stat buf64; int ret = stat64 (name, &buf64); if (!ret) stat64_to_stat32 (&buf64, (struct __stat32 *) buf); return ret; } extern "C" int _stat_r (struct _reent *__restrict ptr, const char *__restrict name, struct stat *__restrict buf) { int ret; if ((ret = stat (name, buf)) == -1) ptr->_errno = get_errno (); return ret; } #endif /* lstat: Provided by SVR4 and 4.3+BSD, POSIX? */ extern "C" int lstat64 (const char *__restrict name, struct stat *__restrict buf) { syscall_printf ("entering"); path_conv pc (name, PC_SYM_NOFOLLOW | PC_POSIX | PC_KEEP_HANDLE, stat_suffixes); return stat_worker (pc, buf); } #ifdef __x86_64__ EXPORT_ALIAS (lstat64, lstat) #else /* lstat: Provided by SVR4 and 4.3+BSD, POSIX? */ extern "C" int lstat (const char *__restrict name, struct stat *__restrict buf) { struct stat buf64; int ret = lstat64 (name, &buf64); if (!ret) stat64_to_stat32 (&buf64, (struct __stat32 *) buf); return ret; } #endif extern "C" int access (const char *fn, int flags) { // flags were incorrectly specified int res = -1; if (flags & ~(F_OK|R_OK|W_OK|X_OK)) set_errno (EINVAL); else { fhandler_base *fh = build_fh_name (fn, PC_SYM_FOLLOW | PC_KEEP_HANDLE, stat_suffixes); if (fh) { res = fh->fhaccess (flags, false); delete fh; } } debug_printf ("returning %d", res); return res; } /* Linux provides this extension; it is basically a wrapper around the POSIX:2008 faccessat (AT_FDCWD, fn, flags, AT_EACCESS). We also provide eaccess as an alias for this, in cygwin.din. */ extern "C" int euidaccess (const char *fn, int flags) { // flags were incorrectly specified int res = -1; if (flags & ~(F_OK|R_OK|W_OK|X_OK)) set_errno (EINVAL); else { fhandler_base *fh = build_fh_name (fn, PC_SYM_FOLLOW | PC_KEEP_HANDLE, stat_suffixes); if (fh) { res = fh->fhaccess (flags, true); delete fh; } } debug_printf ("returning %d", res); return res; } static void rename_append_suffix (path_conv &pc, const char *path, size_t len, const char *suffix) { char buf[len + 5]; if (ascii_strcasematch (path + len - 4, ".lnk") || ascii_strcasematch (path + len - 4, ".exe")) len -= 4; stpcpy (stpncpy (buf, path, len), suffix); pc.check (buf, PC_SYM_NOFOLLOW); } /* This function tests if a filename has one of the "approved" executable suffix. This list is probably not complete... */ static inline bool nt_path_has_executable_suffix (PUNICODE_STRING upath) { static const PUNICODE_STRING blessed_executable_suffixes[] = { &ro_u_com, &ro_u_dll, /* Messy, messy. Per MSDN, the GetBinaryType function is supposed to return with ERROR_BAD_EXE_FORMAT. if the file is a DLL. On 64-bit Windows, this works as expected for 32-bit and 64-bit DLLs. On 32-bit Windows this only works for 32-bit DLLs. For 64-bit DLLs, 32-bit Windows returns true with the type set to SCS_64BIT_BINARY. */ &ro_u_exe, &ro_u_scr, &ro_u_sys, NULL }; USHORT pos = upath->Length / sizeof (WCHAR); PWCHAR path; UNICODE_STRING usuf; const PUNICODE_STRING *suf; /* Too short for a native path? */ if (pos < 8) return false; /* Assumption: All executable suffixes have a length of three. */ path = upath->Buffer + pos - 4; if (*path != L'.') return false; RtlInitCountedUnicodeString (&usuf, path, 4 * sizeof (WCHAR)); for (suf = blessed_executable_suffixes; *suf; ++suf) if (RtlEqualUnicodeString (&usuf, *suf, TRUE)) return true; return false; } extern "C" int rename (const char *oldpath, const char *newpath) { tmp_pathbuf tp; int res = -1; path_conv oldpc, newpc, new2pc, *dstpc, *removepc = NULL; bool old_dir_requested = false, new_dir_requested = false; bool old_explicit_suffix = false, new_explicit_suffix = false; size_t olen, nlen; bool equal_path; NTSTATUS status = STATUS_SUCCESS; HANDLE fh = NULL, nfh; HANDLE old_trans = NULL, trans = NULL; OBJECT_ATTRIBUTES attr; IO_STATUS_BLOCK io; FILE_STANDARD_INFORMATION ofsi; PFILE_RENAME_INFORMATION pfri; __try { if (!*oldpath || !*newpath) { /* Reject rename("","x"), rename("x",""). */ set_errno (ENOENT); __leave; } if (has_dot_last_component (oldpath, true)) { /* Reject rename("dir/.","x"). */ oldpc.check (oldpath, PC_SYM_NOFOLLOW, stat_suffixes); set_errno (oldpc.isdir () ? EINVAL : ENOTDIR); __leave; } if (has_dot_last_component (newpath, true)) { /* Reject rename("dir","x/."). */ newpc.check (newpath, PC_SYM_NOFOLLOW, stat_suffixes); set_errno (!newpc.exists () ? ENOENT : newpc.isdir () ? EINVAL : ENOTDIR); __leave; } /* A trailing slash requires that the pathname points to an existing directory. If it's not, it's a ENOTDIR condition. The same goes for newpath a bit further down this function. */ olen = strlen (oldpath); if (isdirsep (oldpath[olen - 1])) { char *buf; char *p = stpcpy (buf = tp.c_get (), oldpath) - 1; oldpath = buf; while (p >= oldpath && isdirsep (*p)) *p-- = '\0'; olen = p + 1 - oldpath; if (!olen) { /* The root directory cannot be renamed. This also rejects the corner case of rename("/","/"), even though it is the same file. */ set_errno (EINVAL); __leave; } old_dir_requested = true; } oldpc.check (oldpath, PC_SYM_NOFOLLOW, stat_suffixes); if (oldpc.error) { set_errno (oldpc.error); __leave; } if (!oldpc.exists ()) { set_errno (ENOENT); __leave; } if (oldpc.isspecial () && !oldpc.issocket () && !oldpc.is_fs_special ()) { /* No renames from virtual FS */ set_errno (EROFS); __leave; } if (oldpc.has_attribute (FILE_ATTRIBUTE_REPARSE_POINT) && !oldpc.issymlink ()) { /* Volume mount point. If we try to rename a volume mount point, NT returns STATUS_NOT_SAME_DEVICE ==> Win32 ERROR_NOT_SAME_DEVICE ==> errno EXDEV. That's bad since mv(1) will now perform a cross-device move. So what we do here is to treat the volume mount point just like Linux treats a mount point. */ set_errno (EBUSY); __leave; } if (old_dir_requested && !oldpc.isdir ()) { /* Reject rename("file/","x"). */ set_errno (ENOTDIR); __leave; } if (oldpc.known_suffix && (ascii_strcasematch (oldpath + olen - 4, ".lnk") || ascii_strcasematch (oldpath + olen - 4, ".exe"))) old_explicit_suffix = true; nlen = strlen (newpath); if (isdirsep (newpath[nlen - 1])) { char *buf; char *p = stpcpy (buf = tp.c_get (), newpath) - 1; newpath = buf; while (p >= newpath && isdirsep (*p)) *p-- = '\0'; nlen = p + 1 - newpath; if (!nlen) /* The root directory is never empty. */ { set_errno (ENOTEMPTY); __leave; } new_dir_requested = true; } newpc.check (newpath, PC_SYM_NOFOLLOW, stat_suffixes); if (newpc.error) { set_errno (newpc.error); __leave; } if (newpc.isspecial () && !newpc.issocket ()) { /* No renames to virtual FSes */ set_errno (EROFS); __leave; } if (new_dir_requested && !(newpc.exists () ? newpc.isdir () : oldpc.isdir ())) { /* Reject rename("file1","file2/"), but allow rename("dir","d/"). */ set_errno (newpc.exists () ? ENOTDIR : ENOENT); __leave; } if (newpc.exists () && (oldpc.isdir () ? !newpc.isdir () : newpc.isdir ())) { /* Reject rename("file","dir") and rename("dir","file"). */ set_errno (newpc.isdir () ? EISDIR : ENOTDIR); __leave; } if (newpc.known_suffix && (ascii_strcasematch (newpath + nlen - 4, ".lnk") || ascii_strcasematch (newpath + nlen - 4, ".exe"))) new_explicit_suffix = true; /* This test is necessary in almost every case, so do it once here. */ equal_path = RtlEqualUnicodeString (oldpc.get_nt_native_path (), newpc.get_nt_native_path (), oldpc.objcaseinsensitive ()); /* First check if oldpath and newpath only differ by case. If so, it's just a request to change the case of the filename. By simply setting the file attributes to INVALID_FILE_ATTRIBUTES (which translates to "file doesn't exist"), all later tests are skipped. */ if (oldpc.objcaseinsensitive () && newpc.exists () && equal_path && old_explicit_suffix == new_explicit_suffix) { if (RtlEqualUnicodeString (oldpc.get_nt_native_path (), newpc.get_nt_native_path (), FALSE)) { res = 0; __leave; } newpc.file_attributes (INVALID_FILE_ATTRIBUTES); } else if (oldpc.isdir ()) { /* Check for newpath being identical or a subdir of oldpath. */ if (RtlPrefixUnicodeString (oldpc.get_nt_native_path (), newpc.get_nt_native_path (), TRUE)) { if (newpc.get_nt_native_path ()->Length == oldpc.get_nt_native_path ()->Length) { res = 0; __leave; } if (*(PWCHAR) ((PBYTE) newpc.get_nt_native_path ()->Buffer + oldpc.get_nt_native_path ()->Length) == L'\\') { set_errno (EINVAL); __leave; } } } else if (!newpc.exists ()) { if (equal_path && old_explicit_suffix != new_explicit_suffix) { newpc.check (newpath, PC_SYM_NOFOLLOW); if (RtlEqualUnicodeString (oldpc.get_nt_native_path (), newpc.get_nt_native_path (), oldpc.objcaseinsensitive ())) { res = 0; __leave; } } else if (oldpc.is_lnk_special () && !RtlEqualUnicodePathSuffix (newpc.get_nt_native_path (), &ro_u_lnk, TRUE)) rename_append_suffix (newpc, newpath, nlen, ".lnk"); else if (oldpc.is_binary () && !old_explicit_suffix && oldpc.known_suffix && !nt_path_has_executable_suffix (newpc.get_nt_native_path ())) /* Never append .exe suffix if oldpath had .exe suffix given explicitely, or if oldpath wasn't already a .exe file, or if the destination filename has one of the blessed executable suffixes. Note: To rename an executable foo.exe to bar-without-suffix, the .exe suffix must be given explicitly in oldpath. */ rename_append_suffix (newpc, newpath, nlen, ".exe"); } else { if (equal_path && old_explicit_suffix != new_explicit_suffix) { newpc.check (newpath, PC_SYM_NOFOLLOW); if (RtlEqualUnicodeString (oldpc.get_nt_native_path (), newpc.get_nt_native_path (), oldpc.objcaseinsensitive ())) { res = 0; __leave; } } else if (oldpc.is_lnk_special ()) { if (!newpc.is_lnk_special () && !RtlEqualUnicodePathSuffix (newpc.get_nt_native_path (), &ro_u_lnk, TRUE)) { rename_append_suffix (new2pc, newpath, nlen, ".lnk"); removepc = &newpc; } } else if (oldpc.is_binary ()) { /* Never append .exe suffix if oldpath had .exe suffix given explicitely, or if newfile is a binary (in which case the given name probably makes sense as it is), or if the destination filename has one of the blessed executable suffixes. */ if (!old_explicit_suffix && oldpc.known_suffix && !newpc.is_binary () && !nt_path_has_executable_suffix (newpc.get_nt_native_path ())) { rename_append_suffix (new2pc, newpath, nlen, ".exe"); removepc = &newpc; } } else { /* If the new path is an existing .lnk symlink or a .exe file, but the new path has not been specified with explicit suffix, rename to the new name without suffix, as expected, but also remove the clashing symlink or executable. Did I ever mention how I hate the file suffix idea? */ if ((newpc.is_lnk_special () || RtlEqualUnicodePathSuffix (newpc.get_nt_native_path (), &ro_u_exe, TRUE)) && !new_explicit_suffix) { new2pc.check (newpath, PC_SYM_NOFOLLOW, stat_suffixes); newpc.get_nt_native_path ()->Length -= 4 * sizeof (WCHAR); if (new2pc.is_binary () || new2pc.is_lnk_special ()) removepc = &new2pc; } } } dstpc = (removepc == &newpc) ? &new2pc : &newpc; /* Check cross-device before touching anything. Otherwise we might end up with an unlinked target dir even if the actual rename didn't work.*/ if (oldpc.fs_type () != dstpc->fs_type () || oldpc.fs_serial_number () != dstpc->fs_serial_number ()) { set_errno (EXDEV); __leave; } /* Opening the file must be part of the transaction. It's not sufficient to call only NtSetInformationFile under the transaction. Therefore we have to start the transaction here, if necessary. */ if (wincap.has_transactions () && (dstpc->fs_flags () & FILE_SUPPORTS_TRANSACTIONS) && (dstpc->isdir () || (!removepc && dstpc->has_attribute (FILE_ATTRIBUTE_READONLY)))) start_transaction (old_trans, trans); int retry_count; retry_count = 0; retry: /* Talking about inconsistent behaviour... - DELETE is required to rename a file. So far, so good. - At least one cifs FS (Tru64) needs FILE_READ_ATTRIBUTE, otherwise the FileRenameInformation call fails with STATUS_ACCESS_DENIED. However, on NFS we get a STATUS_ACCESS_DENIED if FILE_READ_ATTRIBUTE is used and the file we try to rename is a symlink. Urgh. - Samba (only some versions?) doesn't like the FILE_SHARE_DELETE mode if the file has the R/O attribute set and returns STATUS_ACCESS_DENIED in that case. */ { ULONG access = DELETE | (oldpc.fs_is_cifs () ? FILE_READ_ATTRIBUTES : 0); ULONG sharing = FILE_SHARE_READ | FILE_SHARE_WRITE | (oldpc.fs_is_samba () ? 0 : FILE_SHARE_DELETE); ULONG flags = FILE_OPEN_FOR_BACKUP_INTENT | (oldpc.is_rep_symlink () ? FILE_OPEN_REPARSE_POINT : 0); status = NtOpenFile (&fh, access, oldpc.get_object_attr (attr, sec_none_nih), &io, sharing, flags); } if (!NT_SUCCESS (status)) { debug_printf ("status %y", status); if (status == STATUS_SHARING_VIOLATION && cygwait (10L) != WAIT_SIGNALED) { /* Typical BLODA problem. Some virus scanners check newly generated files and while doing that disallow DELETE access. That's really bad because it breaks applications which copy files by creating a temporary filename and then rename the temp filename to the target filename. This renaming fails due to the jealous virus scanner and the application fails to create the target file. This kludge tries to work around that by yielding until the sharing violation goes away, or a signal arrived, or after about a second, give or take. */ if (++retry_count < 40) { yield (); goto retry; } } else if (NT_TRANSACTIONAL_ERROR (status) && trans) { /* If NtOpenFile fails due to transactional problems, stop transaction and go ahead without. */ stop_transaction (status, old_trans, trans); debug_printf ("Transaction failure. Retry open."); goto retry; } __seterrno_from_nt_status (status); __leave; } /* Renaming a dir to another, existing dir fails always, even if ReplaceIfExists is set to TRUE and the existing dir is empty. So we have to remove the destination dir first. This also covers the case that the destination directory is not empty. In that case, unlink_nt returns with STATUS_DIRECTORY_NOT_EMPTY. */ if (dstpc->isdir ()) { status = unlink_nt (*dstpc); if (!NT_SUCCESS (status)) { __seterrno_from_nt_status (status); __leave; } } /* You can't copy a file if the destination exists and has the R/O attribute set. Remove the R/O attribute first. But first check if a removepc exists. If so, dstpc points to a non-existing file due to a mangled suffix. */ else if (!removepc && dstpc->has_attribute (FILE_ATTRIBUTE_READONLY)) { status = NtOpenFile (&nfh, FILE_WRITE_ATTRIBUTES, dstpc->get_object_attr (attr, sec_none_nih), &io, FILE_SHARE_VALID_FLAGS, FILE_OPEN_FOR_BACKUP_INTENT | (dstpc->is_rep_symlink () ? FILE_OPEN_REPARSE_POINT : 0)); if (!NT_SUCCESS (status)) { __seterrno_from_nt_status (status); __leave; } status = NtSetAttributesFile (nfh, dstpc->file_attributes () & ~FILE_ATTRIBUTE_READONLY); NtClose (nfh); if (!NT_SUCCESS (status)) { __seterrno_from_nt_status (status); __leave; } } /* SUSv3: If the old argument and the new argument resolve to the same existing file, rename() shall return successfully and perform no other action. The test tries to be as quick as possible. Due to the above cross device check we already know both files are on the same device. So it just tests if oldpath has more than 1 hardlink, then it opens newpath and tests for identical file ids. If so, oldpath and newpath refer to the same file. */ if ((removepc || dstpc->exists ()) && !oldpc.isdir () && NT_SUCCESS (NtQueryInformationFile (fh, &io, &ofsi, sizeof ofsi, FileStandardInformation)) && ofsi.NumberOfLinks > 1 && NT_SUCCESS (NtOpenFile (&nfh, READ_CONTROL, (removepc ?: dstpc)->get_object_attr (attr, sec_none_nih), &io, FILE_SHARE_VALID_FLAGS, FILE_OPEN_FOR_BACKUP_INTENT | ((removepc ?: dstpc)->is_rep_symlink () ? FILE_OPEN_REPARSE_POINT : 0)))) { FILE_INTERNAL_INFORMATION ofii, nfii; if (NT_SUCCESS (NtQueryInformationFile (fh, &io, &ofii, sizeof ofii, FileInternalInformation)) && NT_SUCCESS (NtQueryInformationFile (nfh, &io, &nfii, sizeof nfii, FileInternalInformation)) && ofii.FileId.QuadPart == nfii.FileId.QuadPart) { debug_printf ("%s and %s are the same file", oldpath, newpath); NtClose (nfh); res = 0; __leave; } NtClose (nfh); } /* Create FILE_RENAME_INFORMATION struct. Using a tmp_pathbuf area allows for paths of up to 32757 chars. This test is just for paranoia's sake. */ if (dstpc->get_nt_native_path ()->Length > NT_MAX_PATH * sizeof (WCHAR) - sizeof (FILE_RENAME_INFORMATION)) { debug_printf ("target filename too long"); set_errno (EINVAL); __leave; } pfri = (PFILE_RENAME_INFORMATION) tp.w_get (); pfri->ReplaceIfExists = TRUE; pfri->RootDirectory = NULL; pfri->FileNameLength = dstpc->get_nt_native_path ()->Length; memcpy (&pfri->FileName, dstpc->get_nt_native_path ()->Buffer, pfri->FileNameLength); status = NtSetInformationFile (fh, &io, pfri, sizeof *pfri + pfri->FileNameLength, FileRenameInformation); /* This happens if the access rights don't allow deleting the destination. Even if the handle to the original file is opened with BACKUP and/or RECOVERY, these flags don't apply to the destination of the rename operation. So, a privileged user can't rename a file to an existing file, if the permissions of the existing file aren't right. Like directories, we have to handle this separately by removing the destination before renaming. */ if (status == STATUS_ACCESS_DENIED && dstpc->exists () && !dstpc->isdir ()) { if (wincap.has_transactions () && (dstpc->fs_flags () & FILE_SUPPORTS_TRANSACTIONS) && !trans) { start_transaction (old_trans, trans); /* As mentioned earlier, opening the file must be part of the transaction. Therefore we have to reopen the file here if the transaction hasn't been started already. Unfortunately we can't use the NT "reopen file from existing handle" feature. In that case NtOpenFile returns STATUS_TRANSACTIONAL_CONFLICT. We *have* to close the handle to the file first, *then* we can re-open it. Fortunately nothing has happened yet, so the atomicity of the rename functionality is not spoiled. */ NtClose (fh); retry_reopen: status = NtOpenFile (&fh, DELETE, oldpc.get_object_attr (attr, sec_none_nih), &io, FILE_SHARE_VALID_FLAGS, FILE_OPEN_FOR_BACKUP_INTENT | (oldpc.is_rep_symlink () ? FILE_OPEN_REPARSE_POINT : 0)); if (!NT_SUCCESS (status)) { if (NT_TRANSACTIONAL_ERROR (status) && trans) { /* If NtOpenFile fails due to transactional problems, stop transaction and go ahead without. */ stop_transaction (status, old_trans, trans); debug_printf ("Transaction failure. Retry open."); goto retry_reopen; } __seterrno_from_nt_status (status); __leave; } } if (NT_SUCCESS (status = unlink_nt (*dstpc))) status = NtSetInformationFile (fh, &io, pfri, sizeof *pfri + pfri->FileNameLength, FileRenameInformation); } if (NT_SUCCESS (status)) { if (removepc) unlink_nt (*removepc); res = 0; } else __seterrno_from_nt_status (status); } __except (EFAULT) { res = -1; } __endtry if (fh) NtClose (fh); /* Stop transaction if we started one. */ if (trans) stop_transaction (status, old_trans, trans); if (get_errno () != EFAULT) syscall_printf ("%R = rename(%s, %s)", res, oldpath, newpath); return res; } extern "C" int system (const char *cmdstring) { pthread_testcancel (); if (cmdstring == NULL) return 1; int res = -1; const char* command[4]; __try { command[0] = "sh"; command[1] = "-c"; command[2] = cmdstring; command[3] = (const char *) NULL; if ((res = spawnvp (_P_SYSTEM, "/bin/sh", command)) == -1) { // when exec fails, return value should be as if shell // executed exit (127) res = 127; } } __except (EFAULT) {} __endtry return res; } extern "C" int setdtablesize (int size) { if (size < 0) { set_errno (EINVAL); return -1; } if (size <= (int) cygheap->fdtab.size || cygheap->fdtab.extend (size - cygheap->fdtab.size, OPEN_MAX_MAX)) return 0; return -1; } extern "C" int getdtablesize () { return cygheap->fdtab.size; } extern "C" int getpagesize () { return (size_t) wincap.allocation_granularity (); } /* FIXME: not all values are correct... */ extern "C" long int fpathconf (int fd, int v) { cygheap_fdget cfd (fd); if (cfd < 0) return -1; return cfd->fpathconf (v); } extern "C" long int pathconf (const char *file, int v) { fhandler_base *fh = NULL; long ret = -1; __try { if (!*file) { set_errno (ENOENT); return -1; } if (!(fh = build_fh_name (file, PC_SYM_FOLLOW, stat_suffixes))) return -1; if (!fh->exists ()) set_errno (ENOENT); else ret = fh->fpathconf (v); } __except (EFAULT) {} __endtry delete fh; return ret; } extern "C" int ttyname_r (int fd, char *buf, size_t buflen) { int ret = 0; __try { cygheap_fdget cfd (fd, true); if (cfd < 0) ret = EBADF; else if (!cfd->is_tty ()) ret = ENOTTY; else if (buflen < strlen (cfd->ttyname ()) + 1) ret = ERANGE; else strcpy (buf, cfd->ttyname ()); debug_printf ("returning %d tty: %s", ret, ret ? "NULL" : buf); } __except (NO_ERROR) { ret = EFAULT; } __endtry return ret; } extern "C" char * ttyname (int fd) { static char name[TTY_NAME_MAX]; int ret = ttyname_r (fd, name, TTY_NAME_MAX); if (ret) { set_errno (ret); return NULL; } return name; } extern "C" char * ctermid (char *str) { if (str == NULL) str = _my_tls.locals.ttybuf; if (myself->ctty < 0) strcpy (str, "no tty"); else { device d; d.parse (myself->ctty); strcpy (str, d.name); } return str; } /* Tells stdio if it should do the cr/lf conversion for this file */ extern "C" int _cygwin_istext_for_stdio (int fd) { if (CYGWIN_VERSION_OLD_STDIO_CRLF_HANDLING) { syscall_printf ("fd %d: old API", fd); return 0; /* we do it for old apps, due to getc/putc macros */ } cygheap_fdget cfd (fd, false, false); if (cfd < 0) { syscall_printf ("fd %d: not open", fd); return 0; } #if 0 if (cfd->get_device () != FH_FS) { syscall_printf ("fd not disk file. Defaulting to binary."); return 0; } #endif if (cfd->wbinary () || cfd->rbinary ()) { syscall_printf ("fd %d: opened as binary", fd); return 0; } syscall_printf ("fd %d: defaulting to text", fd); return 1; } /* internal newlib function */ extern "C" int _fwalk (struct _reent *ptr, int (*function) (FILE *)); static int setmode_helper (FILE *f) { if (fileno (f) != _my_tls.locals.setmode_file) { syscall_printf ("improbable, but %d != %d", fileno (f), _my_tls.locals.setmode_file); return 0; } syscall_printf ("file was %s now %s", f->_flags & __SCLE ? "text" : "binary", _my_tls.locals.setmode_mode & O_TEXT ? "text" : "binary"); if (_my_tls.locals.setmode_mode & O_TEXT) f->_flags |= __SCLE; else f->_flags &= ~__SCLE; return 0; } extern "C" int getmode (int fd) { cygheap_fdget cfd (fd); if (cfd < 0) return -1; return cfd->get_flags () & (O_BINARY | O_TEXT); } /* Set a file descriptor into text or binary mode, returning the previous mode. */ extern "C" int _setmode (int fd, int mode) { cygheap_fdget cfd (fd); if (cfd < 0) return -1; if (mode != O_BINARY && mode != O_TEXT && mode != 0) { set_errno (EINVAL); return -1; } /* Note that we have no way to indicate the case that writes are binary but not reads, or vice-versa. These cases can arise when using the tty or console interface. People using those interfaces should not use setmode. */ int res; if (cfd->wbinary () && cfd->rbinary ()) res = O_BINARY; else if (cfd->wbinset () && cfd->rbinset ()) res = O_TEXT; /* Specifically set O_TEXT */ else res = 0; if (!mode) cfd->reset_to_open_binmode (); else cfd->set_flags ((cfd->get_flags () & ~(O_TEXT | O_BINARY)) | mode); syscall_printf ("(%d<%S>, %p) returning %s", fd, cfd->pc.get_nt_native_path (), mode, res & O_TEXT ? "text" : "binary"); return res; } extern "C" int cygwin_setmode (int fd, int mode) { int res = _setmode (fd, mode); if (res != -1) { _my_tls.locals.setmode_file = fd; if (_cygwin_istext_for_stdio (fd)) _my_tls.locals.setmode_mode = O_TEXT; else _my_tls.locals.setmode_mode = O_BINARY; _fwalk (_GLOBAL_REENT, setmode_helper); } return res; } extern "C" int posix_fadvise (int fd, off_t offset, off_t len, int advice) { int res = -1; cygheap_fdget cfd (fd); if (cfd >= 0) res = cfd->fadvise (offset, len, advice); else set_errno (EBADF); syscall_printf ("%R = posix_fadvice(%d, %D, %D, %d)", res, fd, offset, len, advice); return res; } extern "C" int posix_fallocate (int fd, off_t offset, off_t len) { int res = -1; if (offset < 0 || len == 0) set_errno (EINVAL); else { cygheap_fdget cfd (fd); if (cfd >= 0) res = cfd->ftruncate (offset + len, false); else set_errno (EBADF); } syscall_printf ("%R = posix_fallocate(%d, %D, %D)", res, fd, offset, len); return res; } extern "C" int ftruncate64 (int fd, off_t length) { int res = -1; cygheap_fdget cfd (fd); if (cfd >= 0) res = cfd->ftruncate (length, true); else set_errno (EBADF); syscall_printf ("%R = ftruncate(%d, %D)", res, fd, length); return res; } #ifdef __x86_64__ EXPORT_ALIAS (ftruncate64, ftruncate) #else /* ftruncate: P96 5.6.7.1 */ extern "C" int ftruncate (int fd, _off_t length) { return ftruncate64 (fd, (off_t)length); } #endif /* truncate: Provided by SVR4 and 4.3+BSD. Not part of POSIX.1 or XPG3 */ extern "C" int truncate64 (const char *pathname, off_t length) { int fd; int res = -1; fd = open (pathname, O_RDWR); if (fd != -1) { res = ftruncate64 (fd, length); close (fd); } syscall_printf ("%R = truncate(%s, %D)", res, pathname, length); return res; } #ifdef __x86_64__ EXPORT_ALIAS (truncate64, truncate) #else /* truncate: Provided by SVR4 and 4.3+BSD. Not part of POSIX.1 or XPG3 */ extern "C" int truncate (const char *pathname, _off_t length) { return truncate64 (pathname, (off_t)length); } #endif extern "C" long _get_osfhandle (int fd) { long res; cygheap_fdget cfd (fd); if (cfd >= 0) res = (long) cfd->get_handle (); else res = -1; syscall_printf ("%R = get_osfhandle(%d)", res, fd); return res; } extern "C" int fstatvfs (int fd, struct statvfs *sfs) { __try { cygheap_fdget cfd (fd); if (cfd < 0) __leave; return cfd->fstatvfs (sfs); } __except (EFAULT) {} __endtry return -1; } extern "C" int statvfs (const char *name, struct statvfs *sfs) { int res = -1; fhandler_base *fh = NULL; __try { if (!(fh = build_fh_name (name, PC_SYM_FOLLOW, stat_suffixes))) __leave; if (fh->error ()) { debug_printf ("got %d error from build_fh_name", fh->error ()); set_errno (fh->error ()); } else if (fh->exists ()) { debug_printf ("(%s, %p), file_attributes %d", name, sfs, (DWORD) *fh); res = fh->fstatvfs (sfs); } else set_errno (ENOENT); } __except (EFAULT) {} __endtry delete fh; MALLOC_CHECK; if (get_errno () != EFAULT) syscall_printf ("%R = statvfs(%s,%p)", res, name, sfs); return res; } extern "C" int fstatfs (int fd, struct statfs *sfs) { struct statvfs vfs; int ret = fstatvfs (fd, &vfs); if (!ret) { sfs->f_type = vfs.f_flag; sfs->f_bsize = vfs.f_bsize; sfs->f_blocks = vfs.f_blocks; sfs->f_bavail = vfs.f_bavail; sfs->f_bfree = vfs.f_bfree; sfs->f_files = -1; sfs->f_ffree = -1; sfs->f_fsid = vfs.f_fsid; sfs->f_namelen = vfs.f_namemax; } return ret; } extern "C" int statfs (const char *fname, struct statfs *sfs) { struct statvfs vfs; int ret = statvfs (fname, &vfs); if (!ret) { sfs->f_type = vfs.f_flag; sfs->f_bsize = vfs.f_bsize; sfs->f_blocks = vfs.f_blocks; sfs->f_bavail = vfs.f_bavail; sfs->f_bfree = vfs.f_bfree; sfs->f_files = -1; sfs->f_ffree = -1; sfs->f_fsid = vfs.f_fsid; sfs->f_namelen = vfs.f_namemax; } return ret; } /* setpgid: POSIX 4.3.3.1 */ extern "C" int setpgid (pid_t pid, pid_t pgid) { int res = -1; if (pid == 0) pid = getpid (); if (pgid == 0) pgid = pid; if (pgid < 0) set_errno (EINVAL); else { pinfo p (pid, PID_MAP_RW); if (!p) set_errno (ESRCH); else if (p->pgid == pgid) res = 0; /* A process may only change the process group of itself and its children */ else if (p != myself && p->ppid != myself->pid) set_errno (EPERM); else { p->pgid = pgid; if (p->pid != p->pgid) p->set_has_pgid_children (0); res = 0; } } syscall_printf ("pid %d, pgid %d, res %d", pid, pgid, res); return res; } extern "C" pid_t getpgid (pid_t pid) { if (pid == 0) pid = getpid (); pinfo p (pid); if (!p) { set_errno (ESRCH); return -1; } return p->pgid; } extern "C" int setpgrp (void) { return setpgid (0, 0); } extern "C" pid_t getpgrp (void) { return getpgid (0); } extern "C" char * ptsname (int fd) { static char buf[TTY_NAME_MAX]; return ptsname_r (fd, buf, sizeof (buf)) == 0 ? buf : NULL; } extern "C" int ptsname_r (int fd, char *buf, size_t buflen) { if (!buf) { set_errno (EINVAL); return EINVAL; } cygheap_fdget cfd (fd); if (cfd < 0) return 0; return cfd->ptsname_r (buf, buflen); } static int __stdcall mknod_worker (const char *path, mode_t type, mode_t mode, _major_t major, _minor_t minor) { char buf[sizeof (":\\00000000:00000000:00000000") + PATH_MAX]; sprintf (buf, ":\\%x:%x:%x", major, minor, type | (mode & (S_IRWXU | S_IRWXG | S_IRWXO))); return symlink_worker (buf, path, true); } extern "C" int mknod32 (const char *path, mode_t mode, dev_t dev) { __try { if (!*path) { set_errno (ENOENT); __leave; } if (strlen (path) >= PATH_MAX) __leave; path_conv w32path (path, PC_SYM_NOFOLLOW); if (w32path.exists ()) { set_errno (EEXIST); __leave; } mode_t type = mode & S_IFMT; _major_t major = _major (dev); _minor_t minor = _minor (dev); switch (type) { case S_IFCHR: case S_IFBLK: break; case S_IFIFO: major = _major (FH_FIFO); minor = _minor (FH_FIFO); break; case 0: case S_IFREG: { int fd = open (path, O_CREAT, mode); if (fd < 0) __leave; close (fd); return 0; } default: set_errno (EINVAL); __leave; } return mknod_worker (w32path.get_win32 (), type, mode, major, minor); } __except (EFAULT) __endtry return -1; } extern "C" int mknod (const char *_path, mode_t mode, __dev16_t dev) { return mknod32 (_path, mode, (dev_t) dev); } extern "C" int mkfifo (const char *path, mode_t mode) { return mknod32 (path, (mode & ~S_IFMT) | S_IFIFO, 0); } /* seteuid: standards? */ extern "C" int seteuid32 (uid_t uid) { debug_printf ("uid: %u myself->uid: %u myself->gid: %u", uid, myself->uid, myself->gid); /* Same uid as we're just running under is usually a no-op. Except we have an external token which is a restricted token. Or, the external token is NULL, but the current impersonation token is a restricted token. This allows to restrict user rights temporarily like this: cygwin_internal(CW_SET_EXTERNAL_TOKEN, restricted_token, CW_TOKEN_RESTRICTED); setuid (getuid ()); [...do stuff with restricted rights...] cygwin_internal(CW_SET_EXTERNAL_TOKEN, INVALID_HANDLE_VALUE, CW_TOKEN_RESTRICTED); setuid (getuid ()); Note that using the current uid is a requirement! Starting with Windows Vista, we have restricted tokens galore (UAC), so this is really just a special case to restict your own processes to lesser rights. */ bool request_restricted_uid_switch = (uid == myself->uid && cygheap->user.ext_token_is_restricted); if (uid == myself->uid && !cygheap->user.groups.ischanged && !request_restricted_uid_switch) { debug_printf ("Nothing happens"); return 0; } cygsid usersid; user_groups &groups = cygheap->user.groups; HANDLE new_token = INVALID_HANDLE_VALUE; struct passwd * pw_new; bool token_is_internal, issamesid = false; pw_new = internal_getpwuid (uid); if (!usersid.getfrompw (pw_new)) { set_errno (EINVAL); return -1; } cygheap->user.deimpersonate (); /* Verify if the process token is suitable. */ /* First of all, skip all checks if a switch to a restricted token has been requested, or if trying to switch back from it. */ if (request_restricted_uid_switch) { if (cygheap->user.external_token != NO_IMPERSONATION) { debug_printf ("Switch to restricted token"); new_token = cygheap->user.external_token; } else { debug_printf ("Switch back from restricted token"); new_token = hProcToken; cygheap->user.ext_token_is_restricted = false; } } /* TODO, CV 2008-11-25: The check against saved_sid is a kludge and a shortcut. We must check if it's really feasible in the long run. The reason to add this shortcut is this: sshd switches back to the privileged user running sshd at least twice in the process of authentication. It calls seteuid first, then setegid. Due to this order, the setgroups group list is still active when calling seteuid and verify_token treats the original token of the privileged user as insufficient. This in turn results in creating a new user token for the privileged user instead of using the orignal token. This can have unfortunate side effects. The created token has different group memberships, different user rights, and misses possible network credentials. Therefore we try this shortcut now. When switching back to the privileged user, we probably always want a correct (aka original) user token for this privileged user, not only in sshd. */ else if ((uid == cygheap->user.saved_uid && usersid == cygheap->user.saved_sid ()) || verify_token (hProcToken, usersid, groups)) new_token = hProcToken; /* Verify if the external token is suitable */ else if (cygheap->user.external_token != NO_IMPERSONATION && verify_token (cygheap->user.external_token, usersid, groups)) new_token = cygheap->user.external_token; /* Verify if the current token (internal or former external) is suitable */ else if (cygheap->user.curr_primary_token != NO_IMPERSONATION && cygheap->user.curr_primary_token != cygheap->user.external_token && verify_token (cygheap->user.curr_primary_token, usersid, groups, &token_is_internal)) new_token = cygheap->user.curr_primary_token; /* Verify if the internal token is suitable */ else if (cygheap->user.internal_token != NO_IMPERSONATION && cygheap->user.internal_token != cygheap->user.curr_primary_token && verify_token (cygheap->user.internal_token, usersid, groups, &token_is_internal)) new_token = cygheap->user.internal_token; debug_printf ("Found token %p", new_token); /* If no impersonation token is available, try to authenticate using LSA private data stored password, LSA authentication using our own LSA module, or, as last chance, NtCreateToken. */ if (new_token == INVALID_HANDLE_VALUE) { new_token = lsaprivkeyauth (pw_new); if (new_token) { /* We have to verify this token since settings in /etc/group might render it unusable im terms of group membership. */ if (!verify_token (new_token, usersid, groups)) { CloseHandle (new_token); new_token = NULL; } } if (!new_token) { debug_printf ("lsaprivkeyauth failed, try lsaauth."); if (!(new_token = lsaauth (usersid, groups, pw_new))) { debug_printf ("lsaauth failed, try create_token."); new_token = create_token (usersid, groups, pw_new); if (new_token == INVALID_HANDLE_VALUE) { debug_printf ("create_token failed, bail out of here"); cygheap->user.reimpersonate (); return -1; } } } /* Keep at most one internal token */ if (cygheap->user.internal_token != NO_IMPERSONATION) CloseHandle (cygheap->user.internal_token); cygheap->user.internal_token = new_token; } if (new_token != hProcToken) { NTSTATUS status; if (!request_restricted_uid_switch) { /* Avoid having HKCU use default user */ WCHAR name[128]; load_registry_hive (usersid.string (name)); } /* Try setting owner to same value as user. */ status = NtSetInformationToken (new_token, TokenOwner, &usersid, sizeof usersid); if (!NT_SUCCESS (status)) debug_printf ("NtSetInformationToken (user.token, TokenOwner), %y", status); /* Try setting primary group in token to current group */ status = NtSetInformationToken (new_token, TokenPrimaryGroup, &groups.pgsid, sizeof (cygsid)); if (!NT_SUCCESS (status)) debug_printf ("NtSetInformationToken (user.token, TokenPrimaryGroup)," "%y", status); /* Try setting default DACL */ PACL dacl_buf = (PACL) alloca (MAX_DACL_LEN (5)); if (sec_acl (dacl_buf, true, true, usersid)) { TOKEN_DEFAULT_DACL tdacl = { dacl_buf }; status = NtSetInformationToken (new_token, TokenDefaultDacl, &tdacl, sizeof (tdacl)); if (!NT_SUCCESS (status)) debug_printf ("NtSetInformationToken (TokenDefaultDacl), %y", status); } } issamesid = (usersid == cygheap->user.sid ()); cygheap->user.set_sid (usersid); cygheap->user.curr_primary_token = new_token == hProcToken ? NO_IMPERSONATION : new_token; cygheap->user.curr_token_is_restricted = false; cygheap->user.setuid_to_restricted = false; if (cygheap->user.curr_imp_token != NO_IMPERSONATION) { CloseHandle (cygheap->user.curr_imp_token); cygheap->user.curr_imp_token = NO_IMPERSONATION; } if (cygheap->user.curr_primary_token != NO_IMPERSONATION) { /* HANDLE_FLAG_INHERIT may be missing in external token. */ if (!SetHandleInformation (cygheap->user.curr_primary_token, HANDLE_FLAG_INHERIT, HANDLE_FLAG_INHERIT) || !DuplicateTokenEx (cygheap->user.curr_primary_token, MAXIMUM_ALLOWED, &sec_none, SecurityImpersonation, TokenImpersonation, &cygheap->user.curr_imp_token)) { __seterrno (); cygheap->user.curr_primary_token = NO_IMPERSONATION; return -1; } cygheap->user.curr_token_is_restricted = request_restricted_uid_switch; set_cygwin_privileges (cygheap->user.curr_primary_token); set_cygwin_privileges (cygheap->user.curr_imp_token); } if (!cygheap->user.reimpersonate ()) { __seterrno (); return -1; } cygheap->user.set_name (pw_new->pw_name); myself->uid = uid; groups.ischanged = FALSE; if (!issamesid) /* Recreate and fill out the user shared region for a new user. */ user_info::create (true); return 0; } #ifdef __x86_64__ EXPORT_ALIAS (seteuid32, seteuid) #else extern "C" int seteuid (__uid16_t uid) { return seteuid32 (uid16touid32 (uid)); } #endif /* setuid: POSIX 4.2.2.1 */ extern "C" int setuid32 (uid_t uid) { int ret = seteuid32 (uid); if (!ret) { cygheap->user.real_uid = myself->uid; /* If restricted token, forget original privileges on exec (). */ cygheap->user.setuid_to_restricted = cygheap->user.curr_token_is_restricted; } debug_printf ("real: %d, effective: %d", cygheap->user.real_uid, myself->uid); return ret; } #ifdef __x86_64__ EXPORT_ALIAS (setuid32, setuid) #else extern "C" int setuid (__uid16_t uid) { return setuid32 (uid16touid32 (uid)); } #endif extern "C" int setreuid32 (uid_t ruid, uid_t euid) { int ret = 0; bool tried = false; uid_t old_euid = myself->uid; if (ruid != ILLEGAL_UID && cygheap->user.real_uid != ruid && euid != ruid) tried = !(ret = seteuid32 (ruid)); if (!ret && euid != ILLEGAL_UID) ret = seteuid32 (euid); if (tried && (ret || euid == ILLEGAL_UID) && seteuid32 (old_euid)) system_printf ("Cannot restore original euid %u", old_euid); if (!ret && ruid != ILLEGAL_UID) cygheap->user.real_uid = ruid; debug_printf ("real: %u, effective: %u", cygheap->user.real_uid, myself->uid); return ret; } #ifdef __x86_64__ EXPORT_ALIAS (setreuid32, setreuid) #else extern "C" int setreuid (__uid16_t ruid, __uid16_t euid) { return setreuid32 (uid16touid32 (ruid), uid16touid32 (euid)); } #endif /* setegid: from System V. */ extern "C" int setegid32 (gid_t gid) { debug_printf ("new egid: %u current: %u", gid, myself->gid); if (gid == myself->gid) { myself->gid = gid; return 0; } NTSTATUS status; user_groups * groups = &cygheap->user.groups; cygsid gsid; struct group * gr = internal_getgrgid (gid); if (!gsid.getfromgr (gr)) { set_errno (EINVAL); return -1; } myself->gid = gid; groups->update_pgrp (gsid); if (cygheap->user.issetuid ()) { /* If impersonated, update impersonation token... */ status = NtSetInformationToken (cygheap->user.primary_token (), TokenPrimaryGroup, &gsid, sizeof gsid); if (!NT_SUCCESS (status)) debug_printf ("NtSetInformationToken (primary_token, " "TokenPrimaryGroup), %y", status); status = NtSetInformationToken (cygheap->user.imp_token (), TokenPrimaryGroup, &gsid, sizeof gsid); if (!NT_SUCCESS (status)) debug_printf ("NtSetInformationToken (token, TokenPrimaryGroup), %y", status); } cygheap->user.deimpersonate (); status = NtSetInformationToken (hProcToken, TokenPrimaryGroup, &gsid, sizeof gsid); if (!NT_SUCCESS (status)) debug_printf ("NtSetInformationToken (hProcToken, TokenPrimaryGroup), %y", status); clear_procimptoken (); cygheap->user.reimpersonate (); return 0; } #ifdef __x86_64__ EXPORT_ALIAS (setegid32, setegid) #else extern "C" int setegid (__gid16_t gid) { return setegid32 (gid16togid32 (gid)); } #endif /* setgid: POSIX 4.2.2.1 */ extern "C" int setgid32 (gid_t gid) { int ret = setegid32 (gid); if (!ret) cygheap->user.real_gid = myself->gid; return ret; } #ifdef __x86_64__ EXPORT_ALIAS (setgid32, setgid) #else extern "C" int setgid (__gid16_t gid) { int ret = setegid32 (gid16togid32 (gid)); if (!ret) cygheap->user.real_gid = myself->gid; return ret; } #endif extern "C" int setregid32 (gid_t rgid, gid_t egid) { int ret = 0; bool tried = false; gid_t old_egid = myself->gid; if (rgid != ILLEGAL_GID && cygheap->user.real_gid != rgid && egid != rgid) tried = !(ret = setegid32 (rgid)); if (!ret && egid != ILLEGAL_GID) ret = setegid32 (egid); if (tried && (ret || egid == ILLEGAL_GID) && setegid32 (old_egid)) system_printf ("Cannot restore original egid %u", old_egid); if (!ret && rgid != ILLEGAL_GID) cygheap->user.real_gid = rgid; debug_printf ("real: %u, effective: %u", cygheap->user.real_gid, myself->gid); return ret; } #ifdef __x86_64__ EXPORT_ALIAS (setregid32, setregid) #else extern "C" int setregid (__gid16_t rgid, __gid16_t egid) { return setregid32 (gid16togid32 (rgid), gid16togid32 (egid)); } #endif /* chroot: privileged Unix system call. */ /* FIXME: Not privileged here. How should this be done? */ extern "C" int chroot (const char *newroot) { path_conv path (newroot, PC_SYM_FOLLOW | PC_POSIX); int ret = -1; if (path.error) set_errno (path.error); else if (!path.exists ()) set_errno (ENOENT); else if (!path.isdir ()) set_errno (ENOTDIR); else if (path.isspecial ()) set_errno (EPERM); else { getwinenv("PATH="); /* Save the native PATH */ cygheap->root.set (path.normalized_path, path.get_win32 (), !!path.objcaseinsensitive ()); ret = 0; } syscall_printf ("%R = chroot(%s)", ret, newroot ?: "NULL"); return ret; } extern "C" int creat (const char *path, mode_t mode) { return open (path, O_WRONLY | O_CREAT | O_TRUNC, mode); } extern "C" void __assertfail () { exit (99); } extern "C" int vhangup () { set_errno (ENOSYS); return -1; } extern "C" int setpriority (int which, id_t who, int value) { DWORD prio = nice_to_winprio (value); int error = 0; switch (which) { case PRIO_PROCESS: if (!who) who = myself->pid; if ((pid_t) who == myself->pid) { if (!SetPriorityClass (GetCurrentProcess (), prio)) { set_errno (EACCES); return -1; } myself->nice = value; debug_printf ("Set nice to %d", myself->nice); return 0; } break; case PRIO_PGRP: if (!who) who = myself->pgid; break; case PRIO_USER: if (!who) who = myself->uid; break; default: set_errno (EINVAL); return -1; } winpids pids ((DWORD) PID_MAP_RW); for (DWORD i = 0; i < pids.npids; ++i) { _pinfo *p = pids[i]; if (p) { switch (which) { case PRIO_PROCESS: if ((pid_t) who != p->pid) continue; break; case PRIO_PGRP: if ((pid_t) who != p->pgid) continue; break; case PRIO_USER: if ((uid_t) who != p->uid) continue; break; } HANDLE proc_h = OpenProcess (PROCESS_SET_INFORMATION, FALSE, p->dwProcessId); if (!proc_h) error = EPERM; else { if (!SetPriorityClass (proc_h, prio)) error = EACCES; else p->nice = value; CloseHandle (proc_h); } } } pids.reset (); if (error) { set_errno (error); return -1; } return 0; } extern "C" int getpriority (int which, id_t who) { int nice = NZERO * 2; /* Illegal value */ switch (which) { case PRIO_PROCESS: if (!who) who = myself->pid; if ((pid_t) who == myself->pid) return myself->nice; break; case PRIO_PGRP: if (!who) who = myself->pgid; break; case PRIO_USER: if (!who) who = myself->uid; break; default: set_errno (EINVAL); return -1; } winpids pids ((DWORD) 0); for (DWORD i = 0; i < pids.npids; ++i) { _pinfo *p = pids[i]; if (p) switch (which) { case PRIO_PROCESS: if ((pid_t) who == p->pid) { nice = p->nice; goto out; } break; case PRIO_PGRP: if ((pid_t) who == p->pgid && p->nice < nice) nice = p->nice; break; case PRIO_USER: if ((uid_t) who == p->uid && p->nice < nice) nice = p->nice; break; } } out: pids.reset (); if (nice == NZERO * 2) { set_errno (ESRCH); return -1; } return nice; } extern "C" int nice (int incr) { return setpriority (PRIO_PROCESS, myself->pid, myself->nice + incr); } /* * Find the first bit set in I. */ extern "C" int ffs (int i) { static const unsigned char table[] = { 0,1,2,2,3,3,3,3,4,4,4,4,4,4,4,4,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5, 6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6, 7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7, 7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7, 8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8, 8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8, 8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8, 8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8 }; unsigned long int a; unsigned long int x = i & -i; a = x <= 0xffff ? (x <= 0xff ? 0 : 8) : (x <= 0xffffff ? 16 : 24); return table[x >> a] + a; } static void locked_append (int fd, const void * buf, size_t size) { struct flock lock_buffer = {F_WRLCK, SEEK_SET, 0, 0, 0}; int count = 0; do if ((lock_buffer.l_start = lseek64 (fd, 0, SEEK_END)) != (off_t) -1 && fcntl64 (fd, F_SETLKW, &lock_buffer) != -1) { if (lseek64 (fd, 0, SEEK_END) != (off_t) -1) write (fd, buf, size); lock_buffer.l_type = F_UNLCK; fcntl64 (fd, F_SETLK, &lock_buffer); break; } while (count++ < 1000 && (errno == EACCES || errno == EAGAIN) && !usleep (1000)); } extern "C" void updwtmp (const char *wtmp_file, const struct utmp *ut) { int fd; if ((fd = open (wtmp_file, O_WRONLY | O_BINARY, 0)) >= 0) { locked_append (fd, ut, sizeof *ut); close (fd); } } static int utmp_fd = -1; static bool utmp_readonly = false; static char *utmp_file = (char *) _PATH_UTMP; static void internal_setutent (bool force_readwrite) { if (force_readwrite && utmp_readonly) endutent (); if (utmp_fd < 0) { utmp_fd = open (utmp_file, O_RDWR | O_BINARY); /* If open fails, we assume an unprivileged process (who?). In this case we try again for reading only unless the process calls pututline() (==force_readwrite) in which case opening just fails. */ if (utmp_fd < 0 && !force_readwrite) { utmp_fd = open (utmp_file, O_RDONLY | O_BINARY); if (utmp_fd >= 0) utmp_readonly = true; } } else lseek (utmp_fd, 0, SEEK_SET); } extern "C" void setutent () { internal_setutent (false); } extern "C" void endutent () { if (utmp_fd >= 0) { close (utmp_fd); utmp_fd = -1; utmp_readonly = false; } } extern "C" void utmpname (const char *file) { __try { if (*file) { endutent (); utmp_file = strdup (file); debug_printf ("New UTMP file: %s", utmp_file); return; } } __except (NO_ERROR) {} __endtry debug_printf ("Invalid file"); } EXPORT_ALIAS (utmpname, utmpxname) /* Note: do not make NO_COPY */ static struct utmp utmp_data_buf[16]; static unsigned utix = 0; #define nutdbuf (sizeof (utmp_data_buf) / sizeof (utmp_data_buf[0])) #define utmp_data ({ \ if (utix >= nutdbuf) \ utix = 0; \ utmp_data_buf + utix++; \ }) static struct utmpx * copy_ut_to_utx (struct utmp *ut, struct utmpx *utx) { if (!ut) return NULL; memcpy (utx, ut, sizeof *ut); utx->ut_tv.tv_sec = ut->ut_time; utx->ut_tv.tv_usec = 0; return utx; } extern "C" struct utmp * getutent () { if (utmp_fd < 0) { internal_setutent (false); if (utmp_fd < 0) return NULL; } utmp *ut = utmp_data; if (read (utmp_fd, ut, sizeof *ut) != sizeof *ut) return NULL; return ut; } extern "C" struct utmp * getutid (const struct utmp *id) { __try { if (utmp_fd < 0) { internal_setutent (false); if (utmp_fd < 0) __leave; } utmp *ut = utmp_data; while (read (utmp_fd, ut, sizeof *ut) == sizeof *ut) { switch (id->ut_type) { case RUN_LVL: case BOOT_TIME: case OLD_TIME: case NEW_TIME: if (id->ut_type == ut->ut_type) return ut; break; case INIT_PROCESS: case LOGIN_PROCESS: case USER_PROCESS: case DEAD_PROCESS: if (strncmp (id->ut_id, ut->ut_id, UT_IDLEN) == 0) return ut; break; default: break; } } } __except (EFAULT) {} __endtry return NULL; } extern "C" struct utmp * getutline (const struct utmp *line) { __try { if (utmp_fd < 0) { internal_setutent (false); if (utmp_fd < 0) __leave; } utmp *ut = utmp_data; while (read (utmp_fd, ut, sizeof *ut) == sizeof *ut) if ((ut->ut_type == LOGIN_PROCESS || ut->ut_type == USER_PROCESS) && !strncmp (ut->ut_line, line->ut_line, sizeof (ut->ut_line))) return ut; } __except (EFAULT) {} __endtry return NULL; } extern "C" struct utmp * pututline (const struct utmp *ut) { __try { internal_setutent (true); if (utmp_fd < 0) { debug_printf ("error: utmp_fd %d", utmp_fd); __leave; } debug_printf ("ut->ut_type %d, ut->ut_pid %d, ut->ut_line '%s', ut->ut_id '%s'\n", ut->ut_type, ut->ut_pid, ut->ut_line, ut->ut_id); debug_printf ("ut->ut_user '%s', ut->ut_host '%s'\n", ut->ut_user, ut->ut_host); struct utmp *u; if ((u = getutid (ut))) { lseek (utmp_fd, -sizeof *ut, SEEK_CUR); write (utmp_fd, ut, sizeof *ut); } else locked_append (utmp_fd, ut, sizeof *ut); /* The documentation says to return a pointer to this which implies that this has to be cast from a const. That doesn't seem right but the documentation seems pretty clear on this. */ return (struct utmp *) ut; } __except (EFAULT) {} __endtry return NULL; } extern "C" void setutxent () { internal_setutent (false); } extern "C" void endutxent () { endutent (); } extern "C" struct utmpx * getutxent () { /* POSIX: Not required to be thread safe. */ static struct utmpx utx; return copy_ut_to_utx (getutent (), &utx); } extern "C" struct utmpx * getutxid (const struct utmpx *id) { /* POSIX: Not required to be thread safe. */ static struct utmpx utx; __try { ((struct utmpx *)id)->ut_time = id->ut_tv.tv_sec; return copy_ut_to_utx (getutid ((struct utmp *) id), &utx); } __except (EFAULT) {} __endtry return NULL; } extern "C" struct utmpx * getutxline (const struct utmpx *line) { /* POSIX: Not required to be thread safe. */ static struct utmpx utx; __try { ((struct utmpx *)line)->ut_time = line->ut_tv.tv_sec; return copy_ut_to_utx (getutline ((struct utmp *) line), &utx); } __except (EFAULT) {} __endtry return NULL; } extern "C" struct utmpx * pututxline (const struct utmpx *utmpx) { /* POSIX: Not required to be thread safe. */ static struct utmpx utx; __try { ((struct utmpx *)utmpx)->ut_time = utmpx->ut_tv.tv_sec; return copy_ut_to_utx (pututline ((struct utmp *) utmpx), &utx); } __except (EFAULT) {} __endtry return NULL; } extern "C" void updwtmpx (const char *wtmpx_file, const struct utmpx *utmpx) { ((struct utmpx *)utmpx)->ut_time = utmpx->ut_tv.tv_sec; updwtmp (wtmpx_file, (const struct utmp *) utmpx); } extern "C" long gethostid (void) { /* Fetch the globally unique MachineGuid value from HKLM/Software/Microsoft/Cryptography and hash it. */ /* Caution: sizeof long might become > 4 when we go 64 bit, but gethostid is supposed to return a 32 bit value, despite the return type long. That's why hostid is *not* long here. */ int32_t hostid = 0x40291372; /* Choose a nice start value */ WCHAR wguid[38]; reg_key key (HKEY_LOCAL_MACHINE, KEY_READ | (wincap.is_wow64() ? KEY_WOW64_64KEY : 0), L"SOFTWARE", L"Microsoft", L"Cryptography", NULL); key.get_string (L"MachineGuid", wguid, 38, L"00000000-0000-0000-0000-000000000000"); /* SDBM hash */ for (PWCHAR wp = wguid; *wp; ++wp) hostid = *wp + (hostid << 6) + (hostid << 16) - hostid; debug_printf ("hostid %08y from MachineGuid %W", hostid, wguid); return (int32_t) hostid; /* Avoid sign extension. */ } #define ETC_SHELLS "/etc/shells" static int shell_index; static struct __sFILE64 *shell_fp; extern "C" char * getusershell () { /* List of default shells if no /etc/shells exists, defined as on Linux. FIXME: SunOS has a far longer list, containing all shells which might be shipped with the OS. Should we do the same for the Cygwin distro, adding bash, tcsh, ksh, pdksh and zsh? */ static const char *def_shells[] = { "/bin/sh", "/bin/csh", "/usr/bin/sh", "/usr/bin/csh", NULL }; static char buf[PATH_MAX]; int ch, buf_idx; if (!shell_fp && !(shell_fp = fopen64 (ETC_SHELLS, "rt"))) { if (def_shells[shell_index]) return strcpy (buf, def_shells[shell_index++]); return NULL; } /* Skip white space characters. */ while ((ch = getc (shell_fp)) != EOF && isspace (ch)) ; /* Get each non-whitespace character as part of the shell path as long as it fits in buf. */ for (buf_idx = 0; ch != EOF && !isspace (ch) && buf_idx < (PATH_MAX - 1); buf_idx++, ch = getc (shell_fp)) buf[buf_idx] = ch; /* Skip any trailing non-whitespace character not fitting in buf. If the path is longer than PATH_MAX, it's invalid anyway. */ while (ch != EOF && !isspace (ch)) ch = getc (shell_fp); if (buf_idx) { buf[buf_idx] = '\0'; return buf; } return NULL; } extern "C" void setusershell () { if (shell_fp) fseek (shell_fp, 0L, SEEK_SET); shell_index = 0; } extern "C" void endusershell () { if (shell_fp) { fclose (shell_fp); shell_fp = NULL; } shell_index = 0; } extern "C" void flockfile (FILE *file) { _flockfile (file); } extern "C" int ftrylockfile (FILE *file) { return _ftrylockfile (file); } extern "C" void funlockfile (FILE *file) { _funlockfile (file); } extern "C" FILE * popen (const char *command, const char *in_type) { const char *type = in_type; char fdopen_flags[3] = "\0\0"; int pipe_flags = 0; #define rw fdopen_flags[0] #define bintext fdopen_flags[1] /* Sanity check. GLibc allows any order and any number of repetition, as long as the string doesn't contradict itself. We do the same here. */ while (*type) { if (*type == 'r' || *type == 'w') { if (rw && rw != *type) break; rw = *type++; } else if (*type == 'b' || *type == 't') { if (bintext && bintext != *type) break; bintext = *type++; } else if (*type == 'e') { pipe_flags = O_CLOEXEC; ++type; } else break; } if ((rw != 'r' && rw != 'w') || (*type != '\0')) { set_errno (EINVAL); return NULL; } int fds[2]; if (pipe2 (fds, pipe_flags) < 0) return NULL; int myix = rw == 'r' ? 0 : 1; lock_process now; FILE *fp = fdopen (fds[myix], fdopen_flags); if (fp) { /* If fds are in the range of stdin/stdout/stderr, move them out of the way (possibly temporarily). Otherwise, spawn_guts will be confused. We do this here rather than adding logic to spawn_guts because spawn_guts is likely to be a more frequently used routine and having stdin/stdout/stderr closed and reassigned to pipe handles is an unlikely event. */ int orig_fds[2] = {fds[0], fds[1]}; for (int i = 0; i < 2; i++) if (fds[i] <= 2) { cygheap_fdnew newfd(3); cygheap->fdtab.move_fd (fds[i], newfd); fds[i] = newfd; } int myfd = fds[myix]; /* myfd - convenience variable for manipulation of the "parent" end of the pipe. */ int stdchild = myix ^ 1; /* stdchild denotes the index into fd for the handle which will be redirected to stdin/stdout */ int __std[2]; __std[myix] = -1; /* -1 means don't pass this fd to the child process */ __std[stdchild] = fds[stdchild]; /* Do pass this as the std handle */ const char *argv[4] = { "/bin/sh", "-c", command, NULL }; /* With 'e' flag given, we have to revert the close-on-exec on the child end of the pipe. Otherwise don't pass our end of the pipe to the child process. */ if (pipe_flags & O_CLOEXEC) fcntl64 (__std[stdchild], F_SETFD, 0); else fcntl64 (myfd, F_SETFD, FD_CLOEXEC); /* Also don't pass the file handle currently associated with stdin/stdout to the child. This function may actually fail if the stdchild fd is closed. But that's ok. */ int stdchild_state = fcntl64 (stdchild, F_GETFD, 0); fcntl64 (stdchild, F_SETFD, stdchild_state | FD_CLOEXEC); /* Start a shell process to run the given command without forking. */ pid_t pid = ch_spawn.worker ("/bin/sh", argv, cur_environ (), _P_NOWAIT, __std[0], __std[1]); /* Reinstate the close-on-exec state */ fcntl64 (stdchild, F_SETFD, stdchild_state); /* If pid >= 0 then spawn_guts succeeded. */ if (pid >= 0) { close (fds[stdchild]); /* Close the child end of the pipe. */ /* Move the fd back to its original slot if it has been moved since we're always supposed to open the lowest numbered available fd and, if fds[mix] != orig_fds[myix] then orig_fds[myix] is presumably lower. */ if (fds[myix] != orig_fds[myix]) cygheap->fdtab.move_fd (fds[myix], myfd = orig_fds[myix]); fhandler_pipe *fh = (fhandler_pipe *) cygheap->fdtab[myfd]; /* Flag that this handle is associated with popen. */ fh->set_popen_pid (pid); return fp; } } /* If we reach here we've seen an error but the pipe handles are open. Close them and return NULL. */ int save_errno = get_errno (); if (fp) { /* Must fclose fp to avoid memory leak. */ fclose (fp); close (fds[myix ^ 1]); } else { close (fds[0]); close (fds[1]); } set_errno (save_errno); #undef rw #undef bintext return NULL; } int pclose (FILE *fp) { fhandler_pipe *fh = (fhandler_pipe *) cygheap->fdtab[fileno(fp)]; if (fh->get_device () != FH_PIPEW && fh->get_device () != FH_PIPER) { set_errno (EBADF); return -1; } int pid = fh->get_popen_pid (); if (!pid) { set_errno (ECHILD); return -1; } if (fclose (fp)) return -1; int status; while (1) if (waitpid (pid, &status, 0) == pid) break; else if (get_errno () == EINTR) continue; else return -1; return status; } /* Preliminary(?) implementation of the openat family of functions. */ static int gen_full_path_at (char *path_ret, int dirfd, const char *pathname, bool null_pathname_allowed = false) { /* Set null_pathname_allowed to true to allow GLIBC compatible behaviour for NULL pathname. Only used by futimesat. */ if (!pathname && !null_pathname_allowed) { set_errno (EFAULT); return -1; } if (pathname) { if (!*pathname) { set_errno (ENOENT); return -1; } if (strlen (pathname) >= PATH_MAX) { set_errno (ENAMETOOLONG); return -1; } } if (pathname && isabspath (pathname)) stpcpy (path_ret, pathname); else { char *p; if (dirfd == AT_FDCWD) { cwdstuff::cwd_lock.acquire (); p = stpcpy (path_ret, cygheap->cwd.get_posix ()); cwdstuff::cwd_lock.release (); } else { cygheap_fdget cfd (dirfd); if (cfd < 0) return -1; if (!cfd->pc.isdir ()) { set_errno (ENOTDIR); return -1; } p = stpcpy (path_ret, cfd->get_name ()); } if (!p) { set_errno (ENOTDIR); return -1; } if (pathname) { if (p[-1] != '/') *p++ = '/'; stpcpy (p, pathname); } } return 0; } extern "C" int openat (int dirfd, const char *pathname, int flags, ...) { tmp_pathbuf tp; __try { char *path = tp.c_get (); if (gen_full_path_at (path, dirfd, pathname)) __leave; va_list ap; mode_t mode; va_start (ap, flags); mode = va_arg (ap, mode_t); va_end (ap); return open (path, flags, mode); } __except (EFAULT) {} __endtry return -1; } extern "C" int faccessat (int dirfd, const char *pathname, int mode, int flags) { tmp_pathbuf tp; int res = -1; __try { char *path = tp.c_get (); if (!gen_full_path_at (path, dirfd, pathname)) { if ((mode & ~(F_OK|R_OK|W_OK|X_OK)) || (flags & ~(AT_SYMLINK_NOFOLLOW|AT_EACCESS))) set_errno (EINVAL); else { fhandler_base *fh = build_fh_name (path, (flags & AT_SYMLINK_NOFOLLOW ? PC_SYM_NOFOLLOW : PC_SYM_FOLLOW) | PC_KEEP_HANDLE, stat_suffixes); if (fh) { res = fh->fhaccess (mode, !!(flags & AT_EACCESS)); delete fh; } } } } __except (EFAULT) {} __endtry debug_printf ("returning %d", res); return res; } extern "C" int fchmodat (int dirfd, const char *pathname, mode_t mode, int flags) { tmp_pathbuf tp; __try { if (flags) { /* BSD has lchmod, but Linux does not. POSIX says AT_SYMLINK_NOFOLLOW is allowed to fail on symlinks; but Linux blindly fails even for non-symlinks. */ set_errno ((flags & ~AT_SYMLINK_NOFOLLOW) ? EINVAL : EOPNOTSUPP); __leave; } char *path = tp.c_get (); if (gen_full_path_at (path, dirfd, pathname)) __leave; return chmod (path, mode); } __except (EFAULT) {} __endtry return -1; } extern "C" int fchownat (int dirfd, const char *pathname, uid_t uid, gid_t gid, int flags) { tmp_pathbuf tp; __try { if (flags & ~AT_SYMLINK_NOFOLLOW) { set_errno (EINVAL); __leave; } char *path = tp.c_get (); if (gen_full_path_at (path, dirfd, pathname)) __leave; return chown_worker (path, (flags & AT_SYMLINK_NOFOLLOW) ? PC_SYM_NOFOLLOW : PC_SYM_FOLLOW, uid, gid); } __except (EFAULT) {} __endtry return -1; } extern "C" int fstatat (int dirfd, const char *__restrict pathname, struct stat *__restrict st, int flags) { tmp_pathbuf tp; __try { if (flags & ~AT_SYMLINK_NOFOLLOW) { set_errno (EINVAL); __leave; } char *path = tp.c_get (); if (gen_full_path_at (path, dirfd, pathname)) __leave; path_conv pc (path, ((flags & AT_SYMLINK_NOFOLLOW) ? PC_SYM_NOFOLLOW : PC_SYM_FOLLOW) | PC_POSIX | PC_KEEP_HANDLE, stat_suffixes); return stat_worker (pc, st); } __except (EFAULT) {} __endtry return -1; } extern int utimens_worker (path_conv &, const struct timespec *); extern "C" int utimensat (int dirfd, const char *pathname, const struct timespec *times, int flags) { tmp_pathbuf tp; __try { char *path = tp.c_get (); if (flags & ~AT_SYMLINK_NOFOLLOW) { set_errno (EINVAL); __leave; } if (gen_full_path_at (path, dirfd, pathname)) __leave; path_conv win32 (path, PC_POSIX | ((flags & AT_SYMLINK_NOFOLLOW) ? PC_SYM_NOFOLLOW : PC_SYM_FOLLOW), stat_suffixes); return utimens_worker (win32, times); } __except (EFAULT) {} __endtry return -1; } extern "C" int futimesat (int dirfd, const char *pathname, const struct timeval *times) { tmp_pathbuf tp; __try { char *path = tp.c_get (); if (gen_full_path_at (path, dirfd, pathname, true)) __leave; return utimes (path, times); } __except (EFAULT) {} __endtry return -1; } extern "C" int linkat (int olddirfd, const char *oldpathname, int newdirfd, const char *newpathname, int flags) { tmp_pathbuf tp; __try { if (flags & ~AT_SYMLINK_FOLLOW) { set_errno (EINVAL); __leave; } char *oldpath = tp.c_get (); if (gen_full_path_at (oldpath, olddirfd, oldpathname)) __leave; char *newpath = tp.c_get (); if (gen_full_path_at (newpath, newdirfd, newpathname)) __leave; if (flags & AT_SYMLINK_FOLLOW) { path_conv old_name (oldpath, PC_SYM_FOLLOW | PC_POSIX, stat_suffixes); if (old_name.error) { set_errno (old_name.error); __leave; } strcpy (oldpath, old_name.normalized_path); } return link (oldpath, newpath); } __except (EFAULT) {} __endtry return -1; } extern "C" int mkdirat (int dirfd, const char *pathname, mode_t mode) { tmp_pathbuf tp; __try { char *path = tp.c_get (); if (gen_full_path_at (path, dirfd, pathname)) __leave; return mkdir (path, mode); } __except (EFAULT) {} __endtry return -1; } extern "C" int mkfifoat (int dirfd, const char *pathname, mode_t mode) { tmp_pathbuf tp; __try { char *path = tp.c_get (); if (gen_full_path_at (path, dirfd, pathname)) __leave; return mkfifo (path, mode); } __except (EFAULT) {} __endtry return -1; } extern "C" int mknodat (int dirfd, const char *pathname, mode_t mode, dev_t dev) { tmp_pathbuf tp; __try { char *path = tp.c_get (); if (gen_full_path_at (path, dirfd, pathname)) __leave; return mknod32 (path, mode, dev); } __except (EFAULT) {} __endtry return -1; } extern "C" ssize_t readlinkat (int dirfd, const char *__restrict pathname, char *__restrict buf, size_t bufsize) { tmp_pathbuf tp; __try { char *path = tp.c_get (); if (gen_full_path_at (path, dirfd, pathname)) __leave; return readlink (path, buf, bufsize); } __except (EFAULT) {} __endtry return -1; } extern "C" int renameat (int olddirfd, const char *oldpathname, int newdirfd, const char *newpathname) { tmp_pathbuf tp; __try { char *oldpath = tp.c_get (); if (gen_full_path_at (oldpath, olddirfd, oldpathname)) __leave; char *newpath = tp.c_get (); if (gen_full_path_at (newpath, newdirfd, newpathname)) __leave; return rename (oldpath, newpath); } __except (EFAULT) {} __endtry return -1; } extern "C" int scandirat (int dirfd, const char *pathname, struct dirent ***namelist, int (*select) (const struct dirent *), int (*compar) (const struct dirent **, const struct dirent **)) { tmp_pathbuf tp; __try { char *path = tp.c_get (); if (gen_full_path_at (path, dirfd, pathname)) __leave; return scandir (pathname, namelist, select, compar); } __except (EFAULT) {} __endtry return -1; } extern "C" int symlinkat (const char *oldpath, int newdirfd, const char *newpathname) { tmp_pathbuf tp; __try { char *newpath = tp.c_get (); if (gen_full_path_at (newpath, newdirfd, newpathname)) __leave; return symlink (oldpath, newpath); } __except (EFAULT) {} __endtry return -1; } extern "C" int unlinkat (int dirfd, const char *pathname, int flags) { tmp_pathbuf tp; __try { if (flags & ~AT_REMOVEDIR) { set_errno (EINVAL); __leave; } char *path = tp.c_get (); if (gen_full_path_at (path, dirfd, pathname)) __leave; return (flags & AT_REMOVEDIR) ? rmdir (path) : unlink (path); } __except (EFAULT) {} __endtry return -1; }