/*- * Copyright (c) 2003-2009 Tim Kientzle * Copyright (c) 2010-2012 Michihiro NAKAJIMA * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer * in this position and unchanged. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR(S) ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR(S) BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "archive_platform.h" __FBSDID("$FreeBSD$"); #if defined(_WIN32) && !defined(__CYGWIN__) #ifdef HAVE_ERRNO_H #include #endif #ifdef HAVE_STDLIB_H #include #endif #include #include "archive.h" #include "archive_string.h" #include "archive_entry.h" #include "archive_private.h" #include "archive_read_disk_private.h" #ifndef O_BINARY #define O_BINARY 0 #endif #ifndef IO_REPARSE_TAG_SYMLINK /* Old SDKs do not provide IO_REPARSE_TAG_SYMLINK */ #define IO_REPARSE_TAG_SYMLINK 0xA000000CL #endif /*- * This is a new directory-walking system that addresses a number * of problems I've had with fts(3). In particular, it has no * pathname-length limits (other than the size of 'int'), handles * deep logical traversals, uses considerably less memory, and has * an opaque interface (easier to modify in the future). * * Internally, it keeps a single list of "tree_entry" items that * represent filesystem objects that require further attention. * Non-directories are not kept in memory: they are pulled from * readdir(), returned to the client, then freed as soon as possible. * Any directory entry to be traversed gets pushed onto the stack. * * There is surprisingly little information that needs to be kept for * each item on the stack. Just the name, depth (represented here as the * string length of the parent directory's pathname), and some markers * indicating how to get back to the parent (via chdir("..") for a * regular dir or via fchdir(2) for a symlink). */ struct restore_time { const wchar_t *full_path; FILETIME lastWriteTime; FILETIME lastAccessTime; mode_t filetype; }; struct tree_entry { int depth; struct tree_entry *next; struct tree_entry *parent; size_t full_path_dir_length; struct archive_wstring name; struct archive_wstring full_path; size_t dirname_length; int64_t dev; int64_t ino; int flags; int filesystem_id; /* How to restore time of a directory. */ struct restore_time restore_time; }; struct filesystem { int64_t dev; int synthetic; int remote; DWORD bytesPerSector; }; /* Definitions for tree_entry.flags bitmap. */ #define isDir 1 /* This entry is a regular directory. */ #define isDirLink 2 /* This entry is a symbolic link to a directory. */ #define needsFirstVisit 4 /* This is an initial entry. */ #define needsDescent 8 /* This entry needs to be previsited. */ #define needsOpen 16 /* This is a directory that needs to be opened. */ #define needsAscent 32 /* This entry needs to be postvisited. */ /* * On Windows, "first visit" is handled as a pattern to be handed to * _findfirst(). This is consistent with Windows conventions that * file patterns are handled within the application. On Posix, * "first visit" is just returned to the client. */ #define MAX_OVERLAPPED 8 #define READ_BUFFER_SIZE (1024 * 64) /* Default to 64KB per https://technet.microsoft.com/en-us/library/cc938632.aspx */ #define DIRECT_IO 0/* Disabled */ #define ASYNC_IO 1/* Enabled */ /* * Local data for this package. */ struct tree { struct tree_entry *stack; struct tree_entry *current; HANDLE d; WIN32_FIND_DATAW _findData; WIN32_FIND_DATAW *findData; int flags; int visit_type; /* Error code from last failed operation. */ int tree_errno; /* A full path with "\\?\" prefix. */ struct archive_wstring full_path; size_t full_path_dir_length; /* Dynamically-sized buffer for holding path */ struct archive_wstring path; /* Last path element */ const wchar_t *basename; /* Leading dir length */ size_t dirname_length; int depth; BY_HANDLE_FILE_INFORMATION lst; BY_HANDLE_FILE_INFORMATION st; int descend; /* How to restore time of a file. */ struct restore_time restore_time; struct entry_sparse { int64_t length; int64_t offset; } *sparse_list, *current_sparse; int sparse_count; int sparse_list_size; char initial_symlink_mode; char symlink_mode; struct filesystem *current_filesystem; struct filesystem *filesystem_table; int initial_filesystem_id; int current_filesystem_id; int max_filesystem_id; int allocated_filesystem; HANDLE entry_fh; int entry_eof; int64_t entry_remaining_bytes; int64_t entry_total; int ol_idx_doing; int ol_idx_done; int ol_num_doing; int ol_num_done; int64_t ol_remaining_bytes; int64_t ol_total; struct la_overlapped { OVERLAPPED ol; struct archive * _a; unsigned char *buff; size_t buff_size; int64_t offset; size_t bytes_expected; size_t bytes_transferred; } ol[MAX_OVERLAPPED]; int direct_io; int async_io; }; #define bhfi_dev(bhfi) ((bhfi)->dwVolumeSerialNumber) /* Treat FileIndex as i-node. We should remove a sequence number * which is high-16-bits of nFileIndexHigh. */ #define bhfi_ino(bhfi) \ ((((int64_t)((bhfi)->nFileIndexHigh & 0x0000FFFFUL)) << 32) \ + (bhfi)->nFileIndexLow) /* Definitions for tree.flags bitmap. */ #define hasStat 16 /* The st entry is valid. */ #define hasLstat 32 /* The lst entry is valid. */ #define needsRestoreTimes 128 static int tree_dir_next_windows(struct tree *t, const wchar_t *pattern); /* Initiate/terminate a tree traversal. */ static struct tree *tree_open(const wchar_t *, int, int); static struct tree *tree_reopen(struct tree *, const wchar_t *, int); static void tree_close(struct tree *); static void tree_free(struct tree *); static void tree_push(struct tree *, const wchar_t *, const wchar_t *, int, int64_t, int64_t, struct restore_time *); /* * tree_next() returns Zero if there is no next entry, non-zero if * there is. Note that directories are visited three times. * Directories are always visited first as part of enumerating their * parent; that is a "regular" visit. If tree_descend() is invoked at * that time, the directory is added to a work list and will * subsequently be visited two more times: once just after descending * into the directory ("postdescent") and again just after ascending * back to the parent ("postascent"). * * TREE_ERROR_DIR is returned if the descent failed (because the * directory couldn't be opened, for instance). This is returned * instead of TREE_POSTDESCENT/TREE_POSTASCENT. TREE_ERROR_DIR is not a * fatal error, but it does imply that the relevant subtree won't be * visited. TREE_ERROR_FATAL is returned for an error that left the * traversal completely hosed. Right now, this is only returned for * chdir() failures during ascent. */ #define TREE_REGULAR 1 #define TREE_POSTDESCENT 2 #define TREE_POSTASCENT 3 #define TREE_ERROR_DIR -1 #define TREE_ERROR_FATAL -2 static int tree_next(struct tree *); /* * Return information about the current entry. */ /* * The current full pathname, length of the full pathname, and a name * that can be used to access the file. Because tree does use chdir * extensively, the access path is almost never the same as the full * current path. * */ static const wchar_t *tree_current_path(struct tree *); static const wchar_t *tree_current_access_path(struct tree *); /* * Request the lstat() or stat() data for the current path. Since the * tree package needs to do some of this anyway, and caches the * results, you should take advantage of it here if you need it rather * than make a redundant stat() or lstat() call of your own. */ static const BY_HANDLE_FILE_INFORMATION *tree_current_stat(struct tree *); static const BY_HANDLE_FILE_INFORMATION *tree_current_lstat(struct tree *); /* The following functions use tricks to avoid a certain number of * stat()/lstat() calls. */ /* "is_physical_dir" is equivalent to S_ISDIR(tree_current_lstat()->st_mode) */ static int tree_current_is_physical_dir(struct tree *); /* "is_physical_link" is equivalent to S_ISLNK(tree_current_lstat()->st_mode) */ static int tree_current_is_physical_link(struct tree *); /* Instead of archive_entry_copy_stat for BY_HANDLE_FILE_INFORMATION */ static void tree_archive_entry_copy_bhfi(struct archive_entry *, struct tree *, const BY_HANDLE_FILE_INFORMATION *); /* "is_dir" is equivalent to S_ISDIR(tree_current_stat()->st_mode) */ static int tree_current_is_dir(struct tree *); static int update_current_filesystem(struct archive_read_disk *a, int64_t dev); static int setup_current_filesystem(struct archive_read_disk *); static int tree_target_is_same_as_parent(struct tree *, const BY_HANDLE_FILE_INFORMATION *); static int _archive_read_disk_open_w(struct archive *, const wchar_t *); static int _archive_read_free(struct archive *); static int _archive_read_close(struct archive *); static int _archive_read_data_block(struct archive *, const void **, size_t *, int64_t *); static int _archive_read_next_header(struct archive *, struct archive_entry **); static int _archive_read_next_header2(struct archive *, struct archive_entry *); static const char *trivial_lookup_gname(void *, int64_t gid); static const char *trivial_lookup_uname(void *, int64_t uid); static int setup_sparse(struct archive_read_disk *, struct archive_entry *); static int close_and_restore_time(HANDLE, struct tree *, struct restore_time *); static int setup_sparse_from_disk(struct archive_read_disk *, struct archive_entry *, HANDLE); static int la_linkname_from_handle(HANDLE, wchar_t **, int *); static int la_linkname_from_pathw(const wchar_t *, wchar_t **, int *); static void entry_symlink_from_pathw(struct archive_entry *, const wchar_t *path); typedef struct _REPARSE_DATA_BUFFER { ULONG ReparseTag; USHORT ReparseDataLength; USHORT Reserved; union { struct { USHORT SubstituteNameOffset; USHORT SubstituteNameLength; USHORT PrintNameOffset; USHORT PrintNameLength; ULONG Flags; WCHAR PathBuffer[1]; } SymbolicLinkReparseBuffer; struct { USHORT SubstituteNameOffset; USHORT SubstituteNameLength; USHORT PrintNameOffset; USHORT PrintNameLength; WCHAR PathBuffer[1]; } MountPointReparseBuffer; struct { UCHAR DataBuffer[1]; } GenericReparseBuffer; } DUMMYUNIONNAME; } REPARSE_DATA_BUFFER, *PREPARSE_DATA_BUFFER; /* * Reads the target of a symbolic link * * Returns 0 on success and -1 on failure * outbuf is allocated in the function */ static int la_linkname_from_handle(HANDLE h, wchar_t **linkname, int *linktype) { DWORD inbytes; REPARSE_DATA_BUFFER *buf; BY_HANDLE_FILE_INFORMATION st; size_t len; BOOL ret; BYTE *indata; wchar_t *tbuf; ret = GetFileInformationByHandle(h, &st); if (ret == 0 || (st.dwFileAttributes & FILE_ATTRIBUTE_REPARSE_POINT) == 0) { return (-1); } indata = malloc(MAXIMUM_REPARSE_DATA_BUFFER_SIZE); ret = DeviceIoControl(h, FSCTL_GET_REPARSE_POINT, NULL, 0, indata, 1024, &inbytes, NULL); if (ret == 0) { la_dosmaperr(GetLastError()); free(indata); return (-1); } buf = (REPARSE_DATA_BUFFER *) indata; if (buf->ReparseTag != IO_REPARSE_TAG_SYMLINK) { free(indata); /* File is not a symbolic link */ errno = EINVAL; return (-1); } len = buf->SymbolicLinkReparseBuffer.SubstituteNameLength; if (len <= 0) { free(indata); return (-1); } tbuf = malloc(len + 1 * sizeof(wchar_t)); if (tbuf == NULL) { free(indata); return (-1); } memcpy(tbuf, &((BYTE *)buf->SymbolicLinkReparseBuffer.PathBuffer) [buf->SymbolicLinkReparseBuffer.SubstituteNameOffset], len); free(indata); tbuf[len / sizeof(wchar_t)] = L'\0'; *linkname = tbuf; /* * Translate backslashes to slashes for libarchive internal use */ while(*tbuf != L'\0') { if (*tbuf == L'\\') *tbuf = L'/'; tbuf++; } if ((st.dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY) == 0) *linktype = AE_SYMLINK_TYPE_FILE; else *linktype = AE_SYMLINK_TYPE_DIRECTORY; return (0); } /* * Returns AE_SYMLINK_TYPE_FILE, AE_SYMLINK_TYPE_DIRECTORY or -1 on error */ static int la_linkname_from_pathw(const wchar_t *path, wchar_t **outbuf, int *linktype) { HANDLE h; const DWORD flag = FILE_FLAG_BACKUP_SEMANTICS | FILE_FLAG_OPEN_REPARSE_POINT; int ret; # if _WIN32_WINNT >= 0x0602 /* _WIN32_WINNT_WIN8 */ CREATEFILE2_EXTENDED_PARAMETERS createExParams; ZeroMemory(&createExParams, sizeof(createExParams)); createExParams.dwSize = sizeof(createExParams); createExParams.dwFileFlags = flag; h = CreateFile2(path, 0, FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE, OPEN_EXISTING, &createExParams); #else h = CreateFileW(path, 0, FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE, NULL, OPEN_EXISTING, flag, NULL); #endif if (h == INVALID_HANDLE_VALUE) { la_dosmaperr(GetLastError()); return (-1); } ret = la_linkname_from_handle(h, outbuf, linktype); CloseHandle(h); return (ret); } static void entry_symlink_from_pathw(struct archive_entry *entry, const wchar_t *path) { wchar_t *linkname = NULL; int ret, linktype; ret = la_linkname_from_pathw(path, &linkname, &linktype); if (ret != 0) return; if (linktype >= 0) { archive_entry_copy_symlink_w(entry, linkname); archive_entry_set_symlink_type(entry, linktype); } free(linkname); return; } static const struct archive_vtable archive_read_disk_vtable = { .archive_free = _archive_read_free, .archive_close = _archive_read_close, .archive_read_data_block = _archive_read_data_block, .archive_read_next_header = _archive_read_next_header, .archive_read_next_header2 = _archive_read_next_header2, }; const char * archive_read_disk_gname(struct archive *_a, la_int64_t gid) { struct archive_read_disk *a = (struct archive_read_disk *)_a; if (ARCHIVE_OK != __archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY, "archive_read_disk_gname")) return (NULL); if (a->lookup_gname == NULL) return (NULL); return ((*a->lookup_gname)(a->lookup_gname_data, gid)); } const char * archive_read_disk_uname(struct archive *_a, la_int64_t uid) { struct archive_read_disk *a = (struct archive_read_disk *)_a; if (ARCHIVE_OK != __archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY, "archive_read_disk_uname")) return (NULL); if (a->lookup_uname == NULL) return (NULL); return ((*a->lookup_uname)(a->lookup_uname_data, uid)); } int archive_read_disk_set_gname_lookup(struct archive *_a, void *private_data, const char * (*lookup_gname)(void *private, la_int64_t gid), void (*cleanup_gname)(void *private)) { struct archive_read_disk *a = (struct archive_read_disk *)_a; archive_check_magic(&a->archive, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY, "archive_read_disk_set_gname_lookup"); if (a->cleanup_gname != NULL && a->lookup_gname_data != NULL) (a->cleanup_gname)(a->lookup_gname_data); a->lookup_gname = lookup_gname; a->cleanup_gname = cleanup_gname; a->lookup_gname_data = private_data; return (ARCHIVE_OK); } int archive_read_disk_set_uname_lookup(struct archive *_a, void *private_data, const char * (*lookup_uname)(void *private, int64_t uid), void (*cleanup_uname)(void *private)) { struct archive_read_disk *a = (struct archive_read_disk *)_a; archive_check_magic(&a->archive, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY, "archive_read_disk_set_uname_lookup"); if (a->cleanup_uname != NULL && a->lookup_uname_data != NULL) (a->cleanup_uname)(a->lookup_uname_data); a->lookup_uname = lookup_uname; a->cleanup_uname = cleanup_uname; a->lookup_uname_data = private_data; return (ARCHIVE_OK); } /* * Create a new archive_read_disk object and initialize it with global state. */ struct archive * archive_read_disk_new(void) { struct archive_read_disk *a; a = (struct archive_read_disk *)calloc(1, sizeof(*a)); if (a == NULL) return (NULL); a->archive.magic = ARCHIVE_READ_DISK_MAGIC; a->archive.state = ARCHIVE_STATE_NEW; a->archive.vtable = &archive_read_disk_vtable; a->entry = archive_entry_new2(&a->archive); a->lookup_uname = trivial_lookup_uname; a->lookup_gname = trivial_lookup_gname; a->flags = ARCHIVE_READDISK_MAC_COPYFILE; return (&a->archive); } static int _archive_read_free(struct archive *_a) { struct archive_read_disk *a = (struct archive_read_disk *)_a; int r; if (_a == NULL) return (ARCHIVE_OK); archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY | ARCHIVE_STATE_FATAL, "archive_read_free"); if (a->archive.state != ARCHIVE_STATE_CLOSED) r = _archive_read_close(&a->archive); else r = ARCHIVE_OK; tree_free(a->tree); if (a->cleanup_gname != NULL && a->lookup_gname_data != NULL) (a->cleanup_gname)(a->lookup_gname_data); if (a->cleanup_uname != NULL && a->lookup_uname_data != NULL) (a->cleanup_uname)(a->lookup_uname_data); archive_string_free(&a->archive.error_string); archive_entry_free(a->entry); a->archive.magic = 0; free(a); return (r); } static int _archive_read_close(struct archive *_a) { struct archive_read_disk *a = (struct archive_read_disk *)_a; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY | ARCHIVE_STATE_FATAL, "archive_read_close"); if (a->archive.state != ARCHIVE_STATE_FATAL) a->archive.state = ARCHIVE_STATE_CLOSED; tree_close(a->tree); return (ARCHIVE_OK); } static void setup_symlink_mode(struct archive_read_disk *a, char symlink_mode, int follow_symlinks) { a->symlink_mode = symlink_mode; a->follow_symlinks = follow_symlinks; if (a->tree != NULL) { a->tree->initial_symlink_mode = a->symlink_mode; a->tree->symlink_mode = a->symlink_mode; } } int archive_read_disk_set_symlink_logical(struct archive *_a) { struct archive_read_disk *a = (struct archive_read_disk *)_a; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY, "archive_read_disk_set_symlink_logical"); setup_symlink_mode(a, 'L', 1); return (ARCHIVE_OK); } int archive_read_disk_set_symlink_physical(struct archive *_a) { struct archive_read_disk *a = (struct archive_read_disk *)_a; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY, "archive_read_disk_set_symlink_physical"); setup_symlink_mode(a, 'P', 0); return (ARCHIVE_OK); } int archive_read_disk_set_symlink_hybrid(struct archive *_a) { struct archive_read_disk *a = (struct archive_read_disk *)_a; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY, "archive_read_disk_set_symlink_hybrid"); setup_symlink_mode(a, 'H', 1);/* Follow symlinks initially. */ return (ARCHIVE_OK); } int archive_read_disk_set_atime_restored(struct archive *_a) { struct archive_read_disk *a = (struct archive_read_disk *)_a; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY, "archive_read_disk_restore_atime"); a->flags |= ARCHIVE_READDISK_RESTORE_ATIME; if (a->tree != NULL) a->tree->flags |= needsRestoreTimes; return (ARCHIVE_OK); } int archive_read_disk_set_behavior(struct archive *_a, int flags) { struct archive_read_disk *a = (struct archive_read_disk *)_a; int r = ARCHIVE_OK; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY, "archive_read_disk_honor_nodump"); a->flags = flags; if (flags & ARCHIVE_READDISK_RESTORE_ATIME) r = archive_read_disk_set_atime_restored(_a); else { if (a->tree != NULL) a->tree->flags &= ~needsRestoreTimes; } return (r); } /* * Trivial implementations of gname/uname lookup functions. * These are normally overridden by the client, but these stub * versions ensure that we always have something that works. */ static const char * trivial_lookup_gname(void *private_data, int64_t gid) { (void)private_data; /* UNUSED */ (void)gid; /* UNUSED */ return (NULL); } static const char * trivial_lookup_uname(void *private_data, int64_t uid) { (void)private_data; /* UNUSED */ (void)uid; /* UNUSED */ return (NULL); } static int64_t align_num_per_sector(struct tree *t, int64_t size) { int64_t surplus; size += t->current_filesystem->bytesPerSector -1; surplus = size % t->current_filesystem->bytesPerSector; size -= surplus; return (size); } static int start_next_async_read(struct archive_read_disk *a, struct tree *t) { struct la_overlapped *olp; DWORD buffbytes, rbytes; if (t->ol_remaining_bytes == 0) return (ARCHIVE_EOF); olp = &(t->ol[t->ol_idx_doing]); t->ol_idx_doing = (t->ol_idx_doing + 1) % MAX_OVERLAPPED; /* Allocate read buffer. */ if (olp->buff == NULL) { void *p; size_t s = (size_t)align_num_per_sector(t, READ_BUFFER_SIZE); p = VirtualAlloc(NULL, s, MEM_COMMIT, PAGE_READWRITE); if (p == NULL) { archive_set_error(&a->archive, ENOMEM, "Couldn't allocate memory"); a->archive.state = ARCHIVE_STATE_FATAL; return (ARCHIVE_FATAL); } olp->buff = p; olp->buff_size = s; olp->_a = &a->archive; olp->ol.hEvent = CreateEventW(NULL, TRUE, FALSE, NULL); if (olp->ol.hEvent == NULL) { la_dosmaperr(GetLastError()); archive_set_error(&a->archive, errno, "CreateEvent failed"); a->archive.state = ARCHIVE_STATE_FATAL; return (ARCHIVE_FATAL); } } else ResetEvent(olp->ol.hEvent); buffbytes = (DWORD)olp->buff_size; if (buffbytes > t->current_sparse->length) buffbytes = (DWORD)t->current_sparse->length; /* Skip hole. */ if (t->current_sparse->offset > t->ol_total) { t->ol_remaining_bytes -= t->current_sparse->offset - t->ol_total; } olp->offset = t->current_sparse->offset; olp->ol.Offset = (DWORD)(olp->offset & 0xffffffff); olp->ol.OffsetHigh = (DWORD)(olp->offset >> 32); if (t->ol_remaining_bytes > buffbytes) { olp->bytes_expected = buffbytes; t->ol_remaining_bytes -= buffbytes; } else { olp->bytes_expected = (size_t)t->ol_remaining_bytes; t->ol_remaining_bytes = 0; } olp->bytes_transferred = 0; t->current_sparse->offset += buffbytes; t->current_sparse->length -= buffbytes; t->ol_total = t->current_sparse->offset; if (t->current_sparse->length == 0 && t->ol_remaining_bytes > 0) t->current_sparse++; if (!ReadFile(t->entry_fh, olp->buff, buffbytes, &rbytes, &(olp->ol))) { DWORD lasterr; lasterr = GetLastError(); if (lasterr == ERROR_HANDLE_EOF) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Reading file truncated"); a->archive.state = ARCHIVE_STATE_FATAL; return (ARCHIVE_FATAL); } else if (lasterr != ERROR_IO_PENDING) { if (lasterr == ERROR_NO_DATA) errno = EAGAIN; else if (lasterr == ERROR_ACCESS_DENIED) errno = EBADF; else la_dosmaperr(lasterr); archive_set_error(&a->archive, errno, "Read error"); a->archive.state = ARCHIVE_STATE_FATAL; return (ARCHIVE_FATAL); } } else olp->bytes_transferred = rbytes; t->ol_num_doing++; return (t->ol_remaining_bytes == 0)? ARCHIVE_EOF: ARCHIVE_OK; } static void cancel_async(struct tree *t) { if (t->ol_num_doing != t->ol_num_done) { CancelIo(t->entry_fh); t->ol_num_doing = t->ol_num_done = 0; } } static int _archive_read_data_block(struct archive *_a, const void **buff, size_t *size, int64_t *offset) { struct archive_read_disk *a = (struct archive_read_disk *)_a; struct tree *t = a->tree; struct la_overlapped *olp; DWORD bytes_transferred; int r = ARCHIVE_FATAL; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_DATA, "archive_read_data_block"); if (t->entry_eof || t->entry_remaining_bytes <= 0) { r = ARCHIVE_EOF; goto abort_read_data; } /* * Make a request to read the file in asynchronous. */ if (t->ol_num_doing == 0) { do { r = start_next_async_read(a, t); if (r == ARCHIVE_FATAL) goto abort_read_data; if (!t->async_io) break; } while (r == ARCHIVE_OK && t->ol_num_doing < MAX_OVERLAPPED); } else { if ((r = start_next_async_read(a, t)) == ARCHIVE_FATAL) goto abort_read_data; } olp = &(t->ol[t->ol_idx_done]); t->ol_idx_done = (t->ol_idx_done + 1) % MAX_OVERLAPPED; if (olp->bytes_transferred) bytes_transferred = (DWORD)olp->bytes_transferred; else if (!GetOverlappedResult(t->entry_fh, &(olp->ol), &bytes_transferred, TRUE)) { la_dosmaperr(GetLastError()); archive_set_error(&a->archive, errno, "GetOverlappedResult failed"); a->archive.state = ARCHIVE_STATE_FATAL; r = ARCHIVE_FATAL; goto abort_read_data; } t->ol_num_done++; if (bytes_transferred == 0 || olp->bytes_expected != bytes_transferred) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Reading file truncated"); a->archive.state = ARCHIVE_STATE_FATAL; r = ARCHIVE_FATAL; goto abort_read_data; } *buff = olp->buff; *size = bytes_transferred; *offset = olp->offset; if (olp->offset > t->entry_total) t->entry_remaining_bytes -= olp->offset - t->entry_total; t->entry_total = olp->offset + *size; t->entry_remaining_bytes -= *size; if (t->entry_remaining_bytes == 0) { /* Close the current file descriptor */ close_and_restore_time(t->entry_fh, t, &t->restore_time); t->entry_fh = INVALID_HANDLE_VALUE; t->entry_eof = 1; } return (ARCHIVE_OK); abort_read_data: *buff = NULL; *size = 0; *offset = t->entry_total; if (t->entry_fh != INVALID_HANDLE_VALUE) { cancel_async(t); /* Close the current file descriptor */ close_and_restore_time(t->entry_fh, t, &t->restore_time); t->entry_fh = INVALID_HANDLE_VALUE; } return (r); } static int next_entry(struct archive_read_disk *a, struct tree *t, struct archive_entry *entry) { const BY_HANDLE_FILE_INFORMATION *st; const BY_HANDLE_FILE_INFORMATION *lst; const char*name; int descend, r; st = NULL; lst = NULL; t->descend = 0; do { switch (tree_next(t)) { case TREE_ERROR_FATAL: archive_set_error(&a->archive, t->tree_errno, "%ls: Unable to continue traversing directory tree", tree_current_path(t)); a->archive.state = ARCHIVE_STATE_FATAL; return (ARCHIVE_FATAL); case TREE_ERROR_DIR: archive_set_error(&a->archive, t->tree_errno, "%ls: Couldn't visit directory", tree_current_path(t)); return (ARCHIVE_FAILED); case 0: return (ARCHIVE_EOF); case TREE_POSTDESCENT: case TREE_POSTASCENT: break; case TREE_REGULAR: lst = tree_current_lstat(t); if (lst == NULL) { archive_set_error(&a->archive, t->tree_errno, "%ls: Cannot stat", tree_current_path(t)); return (ARCHIVE_FAILED); } break; } } while (lst == NULL); archive_entry_copy_pathname_w(entry, tree_current_path(t)); /* * Perform path matching. */ if (a->matching) { r = archive_match_path_excluded(a->matching, entry); if (r < 0) { archive_set_error(&(a->archive), errno, "Failed : %s", archive_error_string(a->matching)); return (r); } if (r) { if (a->excluded_cb_func) a->excluded_cb_func(&(a->archive), a->excluded_cb_data, entry); return (ARCHIVE_RETRY); } } /* * Distinguish 'L'/'P'/'H' symlink following. */ switch(t->symlink_mode) { case 'H': /* 'H': After the first item, rest like 'P'. */ t->symlink_mode = 'P'; /* 'H': First item (from command line) like 'L'. */ /* FALLTHROUGH */ case 'L': /* 'L': Do descend through a symlink to dir. */ descend = tree_current_is_dir(t); /* 'L': Follow symlinks to files. */ a->symlink_mode = 'L'; a->follow_symlinks = 1; /* 'L': Archive symlinks as targets, if we can. */ st = tree_current_stat(t); if (st != NULL && !tree_target_is_same_as_parent(t, st)) break; /* If stat fails, we have a broken symlink; * in that case, don't follow the link. */ /* FALLTHROUGH */ default: /* 'P': Don't descend through a symlink to dir. */ descend = tree_current_is_physical_dir(t); /* 'P': Don't follow symlinks to files. */ a->symlink_mode = 'P'; a->follow_symlinks = 0; /* 'P': Archive symlinks as symlinks. */ st = lst; break; } if (update_current_filesystem(a, bhfi_dev(st)) != ARCHIVE_OK) { a->archive.state = ARCHIVE_STATE_FATAL; return (ARCHIVE_FATAL); } if (t->initial_filesystem_id == -1) t->initial_filesystem_id = t->current_filesystem_id; if (a->flags & ARCHIVE_READDISK_NO_TRAVERSE_MOUNTS) { if (t->initial_filesystem_id != t->current_filesystem_id) return (ARCHIVE_RETRY); } t->descend = descend; tree_archive_entry_copy_bhfi(entry, t, st); /* Save the times to be restored. This must be in before * calling archive_read_disk_descend() or any chance of it, * especially, invoking a callback. */ t->restore_time.lastWriteTime = st->ftLastWriteTime; t->restore_time.lastAccessTime = st->ftLastAccessTime; t->restore_time.filetype = archive_entry_filetype(entry); /* * Perform time matching. */ if (a->matching) { r = archive_match_time_excluded(a->matching, entry); if (r < 0) { archive_set_error(&(a->archive), errno, "Failed : %s", archive_error_string(a->matching)); return (r); } if (r) { if (a->excluded_cb_func) a->excluded_cb_func(&(a->archive), a->excluded_cb_data, entry); return (ARCHIVE_RETRY); } } /* Lookup uname/gname */ name = archive_read_disk_uname(&(a->archive), archive_entry_uid(entry)); if (name != NULL) archive_entry_copy_uname(entry, name); name = archive_read_disk_gname(&(a->archive), archive_entry_gid(entry)); if (name != NULL) archive_entry_copy_gname(entry, name); /* * Perform owner matching. */ if (a->matching) { r = archive_match_owner_excluded(a->matching, entry); if (r < 0) { archive_set_error(&(a->archive), errno, "Failed : %s", archive_error_string(a->matching)); return (r); } if (r) { if (a->excluded_cb_func) a->excluded_cb_func(&(a->archive), a->excluded_cb_data, entry); return (ARCHIVE_RETRY); } } /* * File attributes */ if ((a->flags & ARCHIVE_READDISK_NO_FFLAGS) == 0) { const int supported_attrs = FILE_ATTRIBUTE_READONLY | FILE_ATTRIBUTE_HIDDEN | FILE_ATTRIBUTE_SYSTEM; DWORD file_attrs = st->dwFileAttributes & supported_attrs; if (file_attrs != 0) archive_entry_set_fflags(entry, file_attrs, 0); } /* * Invoke a meta data filter callback. */ if (a->metadata_filter_func) { if (!a->metadata_filter_func(&(a->archive), a->metadata_filter_data, entry)) return (ARCHIVE_RETRY); } archive_entry_copy_sourcepath_w(entry, tree_current_access_path(t)); r = ARCHIVE_OK; if (archive_entry_filetype(entry) == AE_IFREG && archive_entry_size(entry) > 0) { DWORD flags = FILE_FLAG_BACKUP_SEMANTICS; #if _WIN32_WINNT >= 0x0602 /* _WIN32_WINNT_WIN8 */ CREATEFILE2_EXTENDED_PARAMETERS createExParams; #endif if (t->async_io) flags |= FILE_FLAG_OVERLAPPED; if (t->direct_io) flags |= FILE_FLAG_NO_BUFFERING; else flags |= FILE_FLAG_SEQUENTIAL_SCAN; #if _WIN32_WINNT >= 0x0602 /* _WIN32_WINNT_WIN8 */ ZeroMemory(&createExParams, sizeof(createExParams)); createExParams.dwSize = sizeof(createExParams); createExParams.dwFileFlags = flags; t->entry_fh = CreateFile2(tree_current_access_path(t), GENERIC_READ, FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE, OPEN_EXISTING, &createExParams); #else t->entry_fh = CreateFileW(tree_current_access_path(t), GENERIC_READ, FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE, NULL, OPEN_EXISTING, flags, NULL); #endif if (t->entry_fh == INVALID_HANDLE_VALUE) { la_dosmaperr(GetLastError()); archive_set_error(&a->archive, errno, "Couldn't open %ls", tree_current_path(a->tree)); return (ARCHIVE_FAILED); } /* Find sparse data from the disk. */ if ((a->flags & ARCHIVE_READDISK_NO_SPARSE) == 0) { if (archive_entry_hardlink(entry) == NULL && (st->dwFileAttributes & FILE_ATTRIBUTE_SPARSE_FILE) != 0) r = setup_sparse_from_disk(a, entry, t->entry_fh); } } return (r); } static int _archive_read_next_header(struct archive *_a, struct archive_entry **entryp) { int ret; struct archive_read_disk *a = (struct archive_read_disk *)_a; *entryp = NULL; ret = _archive_read_next_header2(_a, a->entry); *entryp = a->entry; return ret; } static int _archive_read_next_header2(struct archive *_a, struct archive_entry *entry) { struct archive_read_disk *a = (struct archive_read_disk *)_a; struct tree *t; int r; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_HEADER | ARCHIVE_STATE_DATA, "archive_read_next_header2"); t = a->tree; if (t->entry_fh != INVALID_HANDLE_VALUE) { cancel_async(t); close_and_restore_time(t->entry_fh, t, &t->restore_time); t->entry_fh = INVALID_HANDLE_VALUE; } archive_entry_clear(entry); while ((r = next_entry(a, t, entry)) == ARCHIVE_RETRY) archive_entry_clear(entry); /* * EOF and FATAL are persistent at this layer. By * modifying the state, we guarantee that future calls to * read a header or read data will fail. */ switch (r) { case ARCHIVE_EOF: a->archive.state = ARCHIVE_STATE_EOF; break; case ARCHIVE_OK: case ARCHIVE_WARN: t->entry_total = 0; if (archive_entry_filetype(entry) == AE_IFREG) { t->entry_remaining_bytes = archive_entry_size(entry); t->entry_eof = (t->entry_remaining_bytes == 0)? 1: 0; if (!t->entry_eof && setup_sparse(a, entry) != ARCHIVE_OK) return (ARCHIVE_FATAL); } else { t->entry_remaining_bytes = 0; t->entry_eof = 1; } t->ol_idx_doing = t->ol_idx_done = 0; t->ol_num_doing = t->ol_num_done = 0; t->ol_remaining_bytes = t->entry_remaining_bytes; t->ol_total = 0; a->archive.state = ARCHIVE_STATE_DATA; break; case ARCHIVE_RETRY: break; case ARCHIVE_FATAL: a->archive.state = ARCHIVE_STATE_FATAL; break; } __archive_reset_read_data(&a->archive); return (r); } static int setup_sparse(struct archive_read_disk *a, struct archive_entry *entry) { struct tree *t = a->tree; int64_t aligned, length, offset; int i; t->sparse_count = archive_entry_sparse_reset(entry); if (t->sparse_count+1 > t->sparse_list_size) { free(t->sparse_list); t->sparse_list_size = t->sparse_count + 1; t->sparse_list = malloc(sizeof(t->sparse_list[0]) * t->sparse_list_size); if (t->sparse_list == NULL) { t->sparse_list_size = 0; archive_set_error(&a->archive, ENOMEM, "Can't allocate data"); a->archive.state = ARCHIVE_STATE_FATAL; return (ARCHIVE_FATAL); } } /* * Get sparse list and make sure those offsets and lengths are * aligned by a sector size. */ for (i = 0; i < t->sparse_count; i++) { archive_entry_sparse_next(entry, &offset, &length); aligned = align_num_per_sector(t, offset); if (aligned != offset) { aligned -= t->current_filesystem->bytesPerSector; length += offset - aligned; } t->sparse_list[i].offset = aligned; aligned = align_num_per_sector(t, length); t->sparse_list[i].length = aligned; } aligned = align_num_per_sector(t, archive_entry_size(entry)); if (i == 0) { t->sparse_list[i].offset = 0; t->sparse_list[i].length = aligned; } else { int j, last = i; t->sparse_list[i].offset = aligned; t->sparse_list[i].length = 0; for (i = 0; i < last; i++) { if ((t->sparse_list[i].offset + t->sparse_list[i].length) <= t->sparse_list[i+1].offset) continue; /* * Now sparse_list[i+1] is overlapped by sparse_list[i]. * Merge those two. */ length = t->sparse_list[i+1].offset - t->sparse_list[i].offset; t->sparse_list[i+1].offset = t->sparse_list[i].offset; t->sparse_list[i+1].length += length; /* Remove sparse_list[i]. */ for (j = i; j < last; j++) { t->sparse_list[j].offset = t->sparse_list[j+1].offset; t->sparse_list[j].length = t->sparse_list[j+1].length; } last--; } } t->current_sparse = t->sparse_list; return (ARCHIVE_OK); } int archive_read_disk_set_matching(struct archive *_a, struct archive *_ma, void (*_excluded_func)(struct archive *, void *, struct archive_entry *), void *_client_data) { struct archive_read_disk *a = (struct archive_read_disk *)_a; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY, "archive_read_disk_set_matching"); a->matching = _ma; a->excluded_cb_func = _excluded_func; a->excluded_cb_data = _client_data; return (ARCHIVE_OK); } int archive_read_disk_set_metadata_filter_callback(struct archive *_a, int (*_metadata_filter_func)(struct archive *, void *, struct archive_entry *), void *_client_data) { struct archive_read_disk *a = (struct archive_read_disk *)_a; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY, "archive_read_disk_set_metadata_filter_callback"); a->metadata_filter_func = _metadata_filter_func; a->metadata_filter_data = _client_data; return (ARCHIVE_OK); } int archive_read_disk_can_descend(struct archive *_a) { struct archive_read_disk *a = (struct archive_read_disk *)_a; struct tree *t = a->tree; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_HEADER | ARCHIVE_STATE_DATA, "archive_read_disk_can_descend"); return (t->visit_type == TREE_REGULAR && t->descend); } /* * Called by the client to mark the directory just returned from * tree_next() as needing to be visited. */ int archive_read_disk_descend(struct archive *_a) { struct archive_read_disk *a = (struct archive_read_disk *)_a; struct tree *t = a->tree; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_HEADER | ARCHIVE_STATE_DATA, "archive_read_disk_descend"); if (!archive_read_disk_can_descend(_a)) return (ARCHIVE_OK); if (tree_current_is_physical_dir(t)) { tree_push(t, t->basename, t->full_path.s, t->current_filesystem_id, bhfi_dev(&(t->lst)), bhfi_ino(&(t->lst)), &t->restore_time); t->stack->flags |= isDir; } else if (tree_current_is_dir(t)) { tree_push(t, t->basename, t->full_path.s, t->current_filesystem_id, bhfi_dev(&(t->st)), bhfi_ino(&(t->st)), &t->restore_time); t->stack->flags |= isDirLink; } t->descend = 0; return (ARCHIVE_OK); } int archive_read_disk_open(struct archive *_a, const char *pathname) { struct archive_read_disk *a = (struct archive_read_disk *)_a; struct archive_wstring wpath; int ret; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_NEW | ARCHIVE_STATE_CLOSED, "archive_read_disk_open"); archive_clear_error(&a->archive); /* Make a wchar_t string from a char string. */ archive_string_init(&wpath); if (archive_wstring_append_from_mbs(&wpath, pathname, strlen(pathname)) != 0) { if (errno == ENOMEM) archive_set_error(&a->archive, ENOMEM, "Can't allocate memory"); else archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Can't convert a path to a wchar_t string"); a->archive.state = ARCHIVE_STATE_FATAL; ret = ARCHIVE_FATAL; } else ret = _archive_read_disk_open_w(_a, wpath.s); archive_wstring_free(&wpath); return (ret); } int archive_read_disk_open_w(struct archive *_a, const wchar_t *pathname) { struct archive_read_disk *a = (struct archive_read_disk *)_a; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_NEW | ARCHIVE_STATE_CLOSED, "archive_read_disk_open_w"); archive_clear_error(&a->archive); return (_archive_read_disk_open_w(_a, pathname)); } static int _archive_read_disk_open_w(struct archive *_a, const wchar_t *pathname) { struct archive_read_disk *a = (struct archive_read_disk *)_a; if (a->tree != NULL) a->tree = tree_reopen(a->tree, pathname, a->flags & ARCHIVE_READDISK_RESTORE_ATIME); else a->tree = tree_open(pathname, a->symlink_mode, a->flags & ARCHIVE_READDISK_RESTORE_ATIME); if (a->tree == NULL) { archive_set_error(&a->archive, ENOMEM, "Can't allocate directory traversal data"); a->archive.state = ARCHIVE_STATE_FATAL; return (ARCHIVE_FATAL); } a->archive.state = ARCHIVE_STATE_HEADER; return (ARCHIVE_OK); } /* * Return a current filesystem ID which is index of the filesystem entry * you've visited through archive_read_disk. */ int archive_read_disk_current_filesystem(struct archive *_a) { struct archive_read_disk *a = (struct archive_read_disk *)_a; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_DATA, "archive_read_disk_current_filesystem"); return (a->tree->current_filesystem_id); } static int update_current_filesystem(struct archive_read_disk *a, int64_t dev) { struct tree *t = a->tree; int i, fid; if (t->current_filesystem != NULL && t->current_filesystem->dev == dev) return (ARCHIVE_OK); for (i = 0; i < t->max_filesystem_id; i++) { if (t->filesystem_table[i].dev == dev) { /* There is the filesystem ID we've already generated. */ t->current_filesystem_id = i; t->current_filesystem = &(t->filesystem_table[i]); return (ARCHIVE_OK); } } /* * There is a new filesystem, we generate a new ID for. */ fid = t->max_filesystem_id++; if (t->max_filesystem_id > t->allocated_filesystem) { size_t s; void *p; s = t->max_filesystem_id * 2; p = realloc(t->filesystem_table, s * sizeof(*t->filesystem_table)); if (p == NULL) { archive_set_error(&a->archive, ENOMEM, "Can't allocate tar data"); return (ARCHIVE_FATAL); } t->filesystem_table = (struct filesystem *)p; t->allocated_filesystem = (int)s; } t->current_filesystem_id = fid; t->current_filesystem = &(t->filesystem_table[fid]); t->current_filesystem->dev = dev; return (setup_current_filesystem(a)); } /* * Returns 1 if current filesystem is generated filesystem, 0 if it is not * or -1 if it is unknown. */ int archive_read_disk_current_filesystem_is_synthetic(struct archive *_a) { struct archive_read_disk *a = (struct archive_read_disk *)_a; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_DATA, "archive_read_disk_current_filesystem"); return (a->tree->current_filesystem->synthetic); } /* * Returns 1 if current filesystem is remote filesystem, 0 if it is not * or -1 if it is unknown. */ int archive_read_disk_current_filesystem_is_remote(struct archive *_a) { struct archive_read_disk *a = (struct archive_read_disk *)_a; archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_DATA, "archive_read_disk_current_filesystem"); return (a->tree->current_filesystem->remote); } /* * If symlink is broken, statfs or statvfs will fail. * Use its directory path instead. */ static wchar_t * safe_path_for_statfs(struct tree *t) { const wchar_t *path; wchar_t *cp, *p = NULL; path = tree_current_access_path(t); if (tree_current_stat(t) == NULL) { p = _wcsdup(path); cp = wcsrchr(p, '/'); if (cp != NULL && wcslen(cp) >= 2) { cp[1] = '.'; cp[2] = '\0'; path = p; } } else p = _wcsdup(path); return (p); } /* * Get conditions of synthetic and remote on Windows */ static int setup_current_filesystem(struct archive_read_disk *a) { struct tree *t = a->tree; wchar_t vol[256]; wchar_t *path; t->current_filesystem->synthetic = -1;/* Not supported */ path = safe_path_for_statfs(t); if (!GetVolumePathNameW(path, vol, sizeof(vol)/sizeof(vol[0]))) { free(path); t->current_filesystem->remote = -1; t->current_filesystem->bytesPerSector = 0; archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "GetVolumePathName failed: %d", (int)GetLastError()); return (ARCHIVE_FAILED); } free(path); switch (GetDriveTypeW(vol)) { case DRIVE_UNKNOWN: case DRIVE_NO_ROOT_DIR: t->current_filesystem->remote = -1; break; case DRIVE_REMOTE: t->current_filesystem->remote = 1; break; default: t->current_filesystem->remote = 0; break; } if (!GetDiskFreeSpaceW(vol, NULL, &(t->current_filesystem->bytesPerSector), NULL, NULL)) { t->current_filesystem->bytesPerSector = 0; archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "GetDiskFreeSpace failed: %d", (int)GetLastError()); return (ARCHIVE_FAILED); } return (ARCHIVE_OK); } static int close_and_restore_time(HANDLE h, struct tree *t, struct restore_time *rt) { HANDLE handle; int r = 0; #if _WIN32_WINNT >= 0x0602 /* _WIN32_WINNT_WIN8 */ CREATEFILE2_EXTENDED_PARAMETERS createExParams; #endif if (h == INVALID_HANDLE_VALUE && AE_IFLNK == rt->filetype) return (0); /* Close a file descriptor. * It will not be used for SetFileTime() because it has been opened * by a read only mode. */ if (h != INVALID_HANDLE_VALUE) CloseHandle(h); if ((t->flags & needsRestoreTimes) == 0) return (r); #if _WIN32_WINNT >= 0x0602 /* _WIN32_WINNT_WIN8 */ ZeroMemory(&createExParams, sizeof(createExParams)); createExParams.dwSize = sizeof(createExParams); createExParams.dwFileFlags = FILE_FLAG_BACKUP_SEMANTICS; handle = CreateFile2(rt->full_path, FILE_WRITE_ATTRIBUTES, 0, OPEN_EXISTING, &createExParams); #else handle = CreateFileW(rt->full_path, FILE_WRITE_ATTRIBUTES, 0, NULL, OPEN_EXISTING, FILE_FLAG_BACKUP_SEMANTICS, NULL); #endif if (handle == INVALID_HANDLE_VALUE) { errno = EINVAL; return (-1); } if (SetFileTime(handle, NULL, &rt->lastAccessTime, &rt->lastWriteTime) == 0) { errno = EINVAL; r = -1; } else r = 0; CloseHandle(handle); return (r); } /* * Add a directory path to the current stack. */ static void tree_push(struct tree *t, const wchar_t *path, const wchar_t *full_path, int filesystem_id, int64_t dev, int64_t ino, struct restore_time *rt) { struct tree_entry *te; te = calloc(1, sizeof(*te)); te->next = t->stack; te->parent = t->current; if (te->parent) te->depth = te->parent->depth + 1; t->stack = te; archive_string_init(&te->name); archive_wstrcpy(&te->name, path); archive_string_init(&te->full_path); archive_wstrcpy(&te->full_path, full_path); te->flags = needsDescent | needsOpen | needsAscent; te->filesystem_id = filesystem_id; te->dev = dev; te->ino = ino; te->dirname_length = t->dirname_length; te->full_path_dir_length = t->full_path_dir_length; te->restore_time.full_path = te->full_path.s; if (rt != NULL) { te->restore_time.lastWriteTime = rt->lastWriteTime; te->restore_time.lastAccessTime = rt->lastAccessTime; te->restore_time.filetype = rt->filetype; } } /* * Append a name to the current dir path. */ static void tree_append(struct tree *t, const wchar_t *name, size_t name_length) { size_t size_needed; t->path.s[t->dirname_length] = L'\0'; t->path.length = t->dirname_length; /* Strip trailing '/' from name, unless entire name is "/". */ while (name_length > 1 && name[name_length - 1] == L'/') name_length--; /* Resize pathname buffer as needed. */ size_needed = name_length + t->dirname_length + 2; archive_wstring_ensure(&t->path, size_needed); /* Add a separating '/' if it's needed. */ if (t->dirname_length > 0 && t->path.s[archive_strlen(&t->path)-1] != L'/') archive_wstrappend_wchar(&t->path, L'/'); t->basename = t->path.s + archive_strlen(&t->path); archive_wstrncat(&t->path, name, name_length); t->restore_time.full_path = t->basename; if (t->full_path_dir_length > 0) { t->full_path.s[t->full_path_dir_length] = L'\0'; t->full_path.length = t->full_path_dir_length; size_needed = name_length + t->full_path_dir_length + 2; archive_wstring_ensure(&t->full_path, size_needed); /* Add a separating '\' if it's needed. */ if (t->full_path.s[archive_strlen(&t->full_path)-1] != L'\\') archive_wstrappend_wchar(&t->full_path, L'\\'); archive_wstrncat(&t->full_path, name, name_length); t->restore_time.full_path = t->full_path.s; } } /* * Open a directory tree for traversal. */ static struct tree * tree_open(const wchar_t *path, int symlink_mode, int restore_time) { struct tree *t; t = calloc(1, sizeof(*t)); archive_string_init(&(t->full_path)); archive_string_init(&t->path); archive_wstring_ensure(&t->path, 15); t->initial_symlink_mode = symlink_mode; return (tree_reopen(t, path, restore_time)); } static struct tree * tree_reopen(struct tree *t, const wchar_t *path, int restore_time) { struct archive_wstring ws; wchar_t *pathname, *p, *base; t->flags = (restore_time != 0)?needsRestoreTimes:0; t->visit_type = 0; t->tree_errno = 0; t->full_path_dir_length = 0; t->dirname_length = 0; t->depth = 0; t->descend = 0; t->current = NULL; t->d = INVALID_HANDLE_VALUE; t->symlink_mode = t->initial_symlink_mode; archive_string_empty(&(t->full_path)); archive_string_empty(&t->path); t->entry_fh = INVALID_HANDLE_VALUE; t->entry_eof = 0; t->entry_remaining_bytes = 0; t->initial_filesystem_id = -1; /* Get wchar_t strings from char strings. */ archive_string_init(&ws); archive_wstrcpy(&ws, path); pathname = ws.s; /* Get a full-path-name. */ p = __la_win_permissive_name_w(pathname); if (p == NULL) goto failed; archive_wstrcpy(&(t->full_path), p); free(p); /* Convert path separators from '\' to '/' */ for (p = pathname; *p != L'\0'; ++p) { if (*p == L'\\') *p = L'/'; } base = pathname; /* First item is set up a lot like a symlink traversal. */ /* printf("Looking for wildcard in %s\n", path); */ if ((base[0] == L'/' && base[1] == L'/' && base[2] == L'?' && base[3] == L'/' && (wcschr(base+4, L'*') || wcschr(base+4, L'?'))) || (!(base[0] == L'/' && base[1] == L'/' && base[2] == L'?' && base[3] == L'/') && (wcschr(base, L'*') || wcschr(base, L'?')))) { // It has a wildcard in it... // Separate the last element. p = wcsrchr(base, L'/'); if (p != NULL) { *p = L'\0'; tree_append(t, base, p - base); t->dirname_length = archive_strlen(&t->path); base = p + 1; } p = wcsrchr(t->full_path.s, L'\\'); if (p != NULL) { *p = L'\0'; t->full_path.length = wcslen(t->full_path.s); t->full_path_dir_length = archive_strlen(&t->full_path); } } tree_push(t, base, t->full_path.s, 0, 0, 0, NULL); archive_wstring_free(&ws); t->stack->flags = needsFirstVisit; /* * Debug flag for Direct IO(No buffering) or Async IO. * Those dependent on environment variable switches * will be removed until next release. */ { const char *e; if ((e = getenv("LIBARCHIVE_DIRECT_IO")) != NULL) { if (e[0] == '0') t->direct_io = 0; else t->direct_io = 1; fprintf(stderr, "LIBARCHIVE_DIRECT_IO=%s\n", (t->direct_io)?"Enabled":"Disabled"); } else t->direct_io = DIRECT_IO; if ((e = getenv("LIBARCHIVE_ASYNC_IO")) != NULL) { if (e[0] == '0') t->async_io = 0; else t->async_io = 1; fprintf(stderr, "LIBARCHIVE_ASYNC_IO=%s\n", (t->async_io)?"Enabled":"Disabled"); } else t->async_io = ASYNC_IO; } return (t); failed: archive_wstring_free(&ws); tree_free(t); return (NULL); } static int tree_descent(struct tree *t) { t->dirname_length = archive_strlen(&t->path); t->full_path_dir_length = archive_strlen(&t->full_path); t->depth++; return (0); } /* * We've finished a directory; ascend back to the parent. */ static int tree_ascend(struct tree *t) { struct tree_entry *te; te = t->stack; t->depth--; close_and_restore_time(INVALID_HANDLE_VALUE, t, &te->restore_time); return (0); } /* * Pop the working stack. */ static void tree_pop(struct tree *t) { struct tree_entry *te; t->full_path.s[t->full_path_dir_length] = L'\0'; t->full_path.length = t->full_path_dir_length; t->path.s[t->dirname_length] = L'\0'; t->path.length = t->dirname_length; if (t->stack == t->current && t->current != NULL) t->current = t->current->parent; te = t->stack; t->stack = te->next; t->dirname_length = te->dirname_length; t->basename = t->path.s + t->dirname_length; t->full_path_dir_length = te->full_path_dir_length; while (t->basename[0] == L'/') t->basename++; archive_wstring_free(&te->name); archive_wstring_free(&te->full_path); free(te); } /* * Get the next item in the tree traversal. */ static int tree_next(struct tree *t) { int r; while (t->stack != NULL) { /* If there's an open dir, get the next entry from there. */ if (t->d != INVALID_HANDLE_VALUE) { r = tree_dir_next_windows(t, NULL); if (r == 0) continue; return (r); } if (t->stack->flags & needsFirstVisit) { wchar_t *d = t->stack->name.s; t->stack->flags &= ~needsFirstVisit; if (!(d[0] == L'/' && d[1] == L'/' && d[2] == L'?' && d[3] == L'/') && (wcschr(d, L'*') || wcschr(d, L'?'))) { r = tree_dir_next_windows(t, d); if (r == 0) continue; return (r); } else { HANDLE h = FindFirstFileW(t->stack->full_path.s, &t->_findData); if (h == INVALID_HANDLE_VALUE) { la_dosmaperr(GetLastError()); t->tree_errno = errno; t->visit_type = TREE_ERROR_DIR; return (t->visit_type); } t->findData = &t->_findData; FindClose(h); } /* Top stack item needs a regular visit. */ t->current = t->stack; tree_append(t, t->stack->name.s, archive_strlen(&(t->stack->name))); //t->dirname_length = t->path_length; //tree_pop(t); t->stack->flags &= ~needsFirstVisit; return (t->visit_type = TREE_REGULAR); } else if (t->stack->flags & needsDescent) { /* Top stack item is dir to descend into. */ t->current = t->stack; tree_append(t, t->stack->name.s, archive_strlen(&(t->stack->name))); t->stack->flags &= ~needsDescent; r = tree_descent(t); if (r != 0) { tree_pop(t); t->visit_type = r; } else t->visit_type = TREE_POSTDESCENT; return (t->visit_type); } else if (t->stack->flags & needsOpen) { t->stack->flags &= ~needsOpen; r = tree_dir_next_windows(t, L"*"); if (r == 0) continue; return (r); } else if (t->stack->flags & needsAscent) { /* Top stack item is dir and we're done with it. */ r = tree_ascend(t); tree_pop(t); t->visit_type = r != 0 ? r : TREE_POSTASCENT; return (t->visit_type); } else { /* Top item on stack is dead. */ tree_pop(t); t->flags &= ~hasLstat; t->flags &= ~hasStat; } } return (t->visit_type = 0); } static int tree_dir_next_windows(struct tree *t, const wchar_t *pattern) { const wchar_t *name; size_t namelen; int r; for (;;) { if (pattern != NULL) { struct archive_wstring pt; archive_string_init(&pt); archive_wstring_ensure(&pt, archive_strlen(&(t->full_path)) + 2 + wcslen(pattern)); archive_wstring_copy(&pt, &(t->full_path)); archive_wstrappend_wchar(&pt, L'\\'); archive_wstrcat(&pt, pattern); t->d = FindFirstFileW(pt.s, &t->_findData); archive_wstring_free(&pt); if (t->d == INVALID_HANDLE_VALUE) { la_dosmaperr(GetLastError()); t->tree_errno = errno; r = tree_ascend(t); /* Undo "chdir" */ tree_pop(t); t->visit_type = r != 0 ? r : TREE_ERROR_DIR; return (t->visit_type); } t->findData = &t->_findData; pattern = NULL; } else if (!FindNextFileW(t->d, &t->_findData)) { FindClose(t->d); t->d = INVALID_HANDLE_VALUE; t->findData = NULL; return (0); } name = t->findData->cFileName; namelen = wcslen(name); t->flags &= ~hasLstat; t->flags &= ~hasStat; if (name[0] == L'.' && name[1] == L'\0') continue; if (name[0] == L'.' && name[1] == L'.' && name[2] == L'\0') continue; tree_append(t, name, namelen); return (t->visit_type = TREE_REGULAR); } } #define EPOC_TIME ARCHIVE_LITERAL_ULL(116444736000000000) static void fileTimeToUtc(const FILETIME *filetime, time_t *t, long *ns) { ULARGE_INTEGER utc; utc.HighPart = filetime->dwHighDateTime; utc.LowPart = filetime->dwLowDateTime; if (utc.QuadPart >= EPOC_TIME) { utc.QuadPart -= EPOC_TIME; /* milli seconds base */ *t = (time_t)(utc.QuadPart / 10000000); /* nano seconds base */ *ns = (long)(utc.QuadPart % 10000000) * 100; } else { *t = 0; *ns = 0; } } static void entry_copy_bhfi(struct archive_entry *entry, const wchar_t *path, const WIN32_FIND_DATAW *findData, const BY_HANDLE_FILE_INFORMATION *bhfi) { time_t secs; long nsecs; mode_t mode; fileTimeToUtc(&bhfi->ftLastAccessTime, &secs, &nsecs); archive_entry_set_atime(entry, secs, nsecs); fileTimeToUtc(&bhfi->ftLastWriteTime, &secs, &nsecs); archive_entry_set_mtime(entry, secs, nsecs); fileTimeToUtc(&bhfi->ftCreationTime, &secs, &nsecs); archive_entry_set_birthtime(entry, secs, nsecs); archive_entry_set_ctime(entry, secs, nsecs); archive_entry_set_dev(entry, bhfi_dev(bhfi)); archive_entry_set_ino64(entry, bhfi_ino(bhfi)); if (bhfi->dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY) archive_entry_set_nlink(entry, bhfi->nNumberOfLinks + 1); else archive_entry_set_nlink(entry, bhfi->nNumberOfLinks); archive_entry_set_size(entry, (((int64_t)bhfi->nFileSizeHigh) << 32) + bhfi->nFileSizeLow); archive_entry_set_uid(entry, 0); archive_entry_set_gid(entry, 0); archive_entry_set_rdev(entry, 0); mode = S_IRUSR | S_IRGRP | S_IROTH; if ((bhfi->dwFileAttributes & FILE_ATTRIBUTE_READONLY) == 0) mode |= S_IWUSR | S_IWGRP | S_IWOTH; if ((bhfi->dwFileAttributes & FILE_ATTRIBUTE_REPARSE_POINT) && findData != NULL && findData->dwReserved0 == IO_REPARSE_TAG_SYMLINK) { mode |= S_IFLNK; entry_symlink_from_pathw(entry, path); } else if (bhfi->dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY) mode |= S_IFDIR | S_IXUSR | S_IXGRP | S_IXOTH; else { const wchar_t *p; mode |= S_IFREG; p = wcsrchr(path, L'.'); if (p != NULL && wcslen(p) == 4) { switch (p[1]) { case L'B': case L'b': if ((p[2] == L'A' || p[2] == L'a' ) && (p[3] == L'T' || p[3] == L't' )) mode |= S_IXUSR | S_IXGRP | S_IXOTH; break; case L'C': case L'c': if (((p[2] == L'M' || p[2] == L'm' ) && (p[3] == L'D' || p[3] == L'd' ))) mode |= S_IXUSR | S_IXGRP | S_IXOTH; break; case L'E': case L'e': if ((p[2] == L'X' || p[2] == L'x' ) && (p[3] == L'E' || p[3] == L'e' )) mode |= S_IXUSR | S_IXGRP | S_IXOTH; break; default: break; } } } archive_entry_set_mode(entry, mode); } static void tree_archive_entry_copy_bhfi(struct archive_entry *entry, struct tree *t, const BY_HANDLE_FILE_INFORMATION *bhfi) { entry_copy_bhfi(entry, tree_current_path(t), t->findData, bhfi); } static int tree_current_file_information(struct tree *t, BY_HANDLE_FILE_INFORMATION *st, int sim_lstat) { HANDLE h; int r; DWORD flag = FILE_FLAG_BACKUP_SEMANTICS; # if _WIN32_WINNT >= 0x0602 /* _WIN32_WINNT_WIN8 */ CREATEFILE2_EXTENDED_PARAMETERS createExParams; #endif if (sim_lstat && tree_current_is_physical_link(t)) flag |= FILE_FLAG_OPEN_REPARSE_POINT; # if _WIN32_WINNT >= 0x0602 /* _WIN32_WINNT_WIN8 */ ZeroMemory(&createExParams, sizeof(createExParams)); createExParams.dwSize = sizeof(createExParams); createExParams.dwFileFlags = flag; h = CreateFile2(tree_current_access_path(t), 0, FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE, OPEN_EXISTING, &createExParams); #else h = CreateFileW(tree_current_access_path(t), 0, FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE, NULL, OPEN_EXISTING, flag, NULL); #endif if (h == INVALID_HANDLE_VALUE) { la_dosmaperr(GetLastError()); t->tree_errno = errno; return (0); } r = GetFileInformationByHandle(h, st); CloseHandle(h); return (r); } /* * Get the stat() data for the entry just returned from tree_next(). */ static const BY_HANDLE_FILE_INFORMATION * tree_current_stat(struct tree *t) { if (!(t->flags & hasStat)) { if (!tree_current_file_information(t, &t->st, 0)) return NULL; t->flags |= hasStat; } return (&t->st); } /* * Get the lstat() data for the entry just returned from tree_next(). */ static const BY_HANDLE_FILE_INFORMATION * tree_current_lstat(struct tree *t) { if (!(t->flags & hasLstat)) { if (!tree_current_file_information(t, &t->lst, 1)) return NULL; t->flags |= hasLstat; } return (&t->lst); } /* * Test whether current entry is a dir or link to a dir. */ static int tree_current_is_dir(struct tree *t) { if (t->findData) return (t->findData->dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY); return (0); } /* * Test whether current entry is a physical directory. Usually, we * already have at least one of stat() or lstat() in memory, so we * use tricks to try to avoid an extra trip to the disk. */ static int tree_current_is_physical_dir(struct tree *t) { if (tree_current_is_physical_link(t)) return (0); return (tree_current_is_dir(t)); } /* * Test whether current entry is a symbolic link. */ static int tree_current_is_physical_link(struct tree *t) { if (t->findData) return ((t->findData->dwFileAttributes & FILE_ATTRIBUTE_REPARSE_POINT) && (t->findData->dwReserved0 == IO_REPARSE_TAG_SYMLINK)); return (0); } /* * Test whether the same file has been in the tree as its parent. */ static int tree_target_is_same_as_parent(struct tree *t, const BY_HANDLE_FILE_INFORMATION *st) { struct tree_entry *te; int64_t dev = bhfi_dev(st); int64_t ino = bhfi_ino(st); for (te = t->current->parent; te != NULL; te = te->parent) { if (te->dev == dev && te->ino == ino) return (1); } return (0); } /* * Return the access path for the entry just returned from tree_next(). */ static const wchar_t * tree_current_access_path(struct tree *t) { return (t->full_path.s); } /* * Return the full path for the entry just returned from tree_next(). */ static const wchar_t * tree_current_path(struct tree *t) { return (t->path.s); } /* * Terminate the traversal. */ static void tree_close(struct tree *t) { if (t == NULL) return; if (t->entry_fh != INVALID_HANDLE_VALUE) { cancel_async(t); close_and_restore_time(t->entry_fh, t, &t->restore_time); t->entry_fh = INVALID_HANDLE_VALUE; } /* Close the handle of FindFirstFileW */ if (t->d != INVALID_HANDLE_VALUE) { FindClose(t->d); t->d = INVALID_HANDLE_VALUE; t->findData = NULL; } /* Release anything remaining in the stack. */ while (t->stack != NULL) tree_pop(t); } /* * Release any resources. */ static void tree_free(struct tree *t) { int i; if (t == NULL) return; archive_wstring_free(&t->path); archive_wstring_free(&t->full_path); free(t->sparse_list); free(t->filesystem_table); for (i = 0; i < MAX_OVERLAPPED; i++) { if (t->ol[i].buff) VirtualFree(t->ol[i].buff, 0, MEM_RELEASE); CloseHandle(t->ol[i].ol.hEvent); } free(t); } /* * Populate the archive_entry with metadata from the disk. */ int archive_read_disk_entry_from_file(struct archive *_a, struct archive_entry *entry, int fd, const struct stat *st) { struct archive_read_disk *a = (struct archive_read_disk *)_a; const wchar_t *path; const wchar_t *wname; const char *name; HANDLE h; BY_HANDLE_FILE_INFORMATION bhfi; DWORD fileAttributes = 0; int r; archive_clear_error(_a); wname = archive_entry_sourcepath_w(entry); if (wname == NULL) wname = archive_entry_pathname_w(entry); if (wname == NULL) { archive_set_error(&a->archive, EINVAL, "Can't get a wide character version of the path"); return (ARCHIVE_FAILED); } path = __la_win_permissive_name_w(wname); if (st == NULL) { /* * Get metadata through GetFileInformationByHandle(). */ if (fd >= 0) { h = (HANDLE)_get_osfhandle(fd); r = GetFileInformationByHandle(h, &bhfi); if (r == 0) { la_dosmaperr(GetLastError()); archive_set_error(&a->archive, errno, "Can't GetFileInformationByHandle"); return (ARCHIVE_FAILED); } entry_copy_bhfi(entry, path, NULL, &bhfi); } else { WIN32_FIND_DATAW findData; DWORD flag, desiredAccess; # if _WIN32_WINNT >= 0x0602 /* _WIN32_WINNT_WIN8 */ CREATEFILE2_EXTENDED_PARAMETERS createExParams; #endif h = FindFirstFileW(path, &findData); if (h == INVALID_HANDLE_VALUE) { la_dosmaperr(GetLastError()); archive_set_error(&a->archive, errno, "Can't FindFirstFileW"); return (ARCHIVE_FAILED); } FindClose(h); flag = FILE_FLAG_BACKUP_SEMANTICS; if (!a->follow_symlinks && (findData.dwFileAttributes & FILE_ATTRIBUTE_REPARSE_POINT) && (findData.dwReserved0 == IO_REPARSE_TAG_SYMLINK)) { flag |= FILE_FLAG_OPEN_REPARSE_POINT; desiredAccess = 0; } else if (findData.dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY) { desiredAccess = 0; } else desiredAccess = GENERIC_READ; # if _WIN32_WINNT >= 0x0602 /* _WIN32_WINNT_WIN8 */ ZeroMemory(&createExParams, sizeof(createExParams)); createExParams.dwSize = sizeof(createExParams); createExParams.dwFileFlags = flag; h = CreateFile2(path, desiredAccess, FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE, OPEN_EXISTING, &createExParams); #else h = CreateFileW(path, desiredAccess, FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE, NULL, OPEN_EXISTING, flag, NULL); #endif if (h == INVALID_HANDLE_VALUE) { la_dosmaperr(GetLastError()); archive_set_error(&a->archive, errno, "Can't CreateFileW"); return (ARCHIVE_FAILED); } r = GetFileInformationByHandle(h, &bhfi); if (r == 0) { la_dosmaperr(GetLastError()); archive_set_error(&a->archive, errno, "Can't GetFileInformationByHandle"); CloseHandle(h); return (ARCHIVE_FAILED); } entry_copy_bhfi(entry, path, &findData, &bhfi); } fileAttributes = bhfi.dwFileAttributes; } else { archive_entry_copy_stat(entry, st); if (st->st_mode & S_IFLNK) entry_symlink_from_pathw(entry, path); h = INVALID_HANDLE_VALUE; } /* Lookup uname/gname */ name = archive_read_disk_uname(_a, archive_entry_uid(entry)); if (name != NULL) archive_entry_copy_uname(entry, name); name = archive_read_disk_gname(_a, archive_entry_gid(entry)); if (name != NULL) archive_entry_copy_gname(entry, name); /* * File attributes */ if ((a->flags & ARCHIVE_READDISK_NO_FFLAGS) == 0) { const int supported_attrs = FILE_ATTRIBUTE_READONLY | FILE_ATTRIBUTE_HIDDEN | FILE_ATTRIBUTE_SYSTEM; DWORD file_attrs = fileAttributes & supported_attrs; if (file_attrs != 0) archive_entry_set_fflags(entry, file_attrs, 0); } /* * Can this file be sparse file ? */ if (archive_entry_filetype(entry) != AE_IFREG || archive_entry_size(entry) <= 0 || archive_entry_hardlink(entry) != NULL) { if (h != INVALID_HANDLE_VALUE && fd < 0) CloseHandle(h); return (ARCHIVE_OK); } if (h == INVALID_HANDLE_VALUE) { if (fd >= 0) { h = (HANDLE)_get_osfhandle(fd); } else { # if _WIN32_WINNT >= 0x0602 /* _WIN32_WINNT_WIN8 */ CREATEFILE2_EXTENDED_PARAMETERS createExParams; ZeroMemory(&createExParams, sizeof(createExParams)); createExParams.dwSize = sizeof(createExParams); createExParams.dwFileFlags = FILE_FLAG_BACKUP_SEMANTICS; h = CreateFile2(path, GENERIC_READ, FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE, OPEN_EXISTING, &createExParams); #else h = CreateFileW(path, GENERIC_READ, FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE, NULL, OPEN_EXISTING, FILE_FLAG_BACKUP_SEMANTICS, NULL); #endif if (h == INVALID_HANDLE_VALUE) { la_dosmaperr(GetLastError()); archive_set_error(&a->archive, errno, "Can't CreateFileW"); return (ARCHIVE_FAILED); } } r = GetFileInformationByHandle(h, &bhfi); if (r == 0) { la_dosmaperr(GetLastError()); archive_set_error(&a->archive, errno, "Can't GetFileInformationByHandle"); if (h != INVALID_HANDLE_VALUE && fd < 0) CloseHandle(h); return (ARCHIVE_FAILED); } fileAttributes = bhfi.dwFileAttributes; } /* Sparse file must be set a mark, FILE_ATTRIBUTE_SPARSE_FILE */ if ((fileAttributes & FILE_ATTRIBUTE_SPARSE_FILE) == 0) { if (fd < 0) CloseHandle(h); return (ARCHIVE_OK); } if ((a->flags & ARCHIVE_READDISK_NO_SPARSE) == 0) { r = setup_sparse_from_disk(a, entry, h); if (fd < 0) CloseHandle(h); } return (r); } /* * Windows sparse interface. */ #if defined(__MINGW32__) && !defined(FSCTL_QUERY_ALLOCATED_RANGES) #define FSCTL_QUERY_ALLOCATED_RANGES 0x940CF typedef struct { LARGE_INTEGER FileOffset; LARGE_INTEGER Length; } FILE_ALLOCATED_RANGE_BUFFER; #endif static int setup_sparse_from_disk(struct archive_read_disk *a, struct archive_entry *entry, HANDLE handle) { FILE_ALLOCATED_RANGE_BUFFER range, *outranges = NULL; size_t outranges_size; int64_t entry_size = archive_entry_size(entry); int exit_sts = ARCHIVE_OK; range.FileOffset.QuadPart = 0; range.Length.QuadPart = entry_size; outranges_size = 2048; outranges = (FILE_ALLOCATED_RANGE_BUFFER *)malloc(outranges_size); if (outranges == NULL) { archive_set_error(&a->archive, ENOMEM, "Couldn't allocate memory"); exit_sts = ARCHIVE_FATAL; goto exit_setup_sparse; } for (;;) { DWORD retbytes; BOOL ret; for (;;) { ret = DeviceIoControl(handle, FSCTL_QUERY_ALLOCATED_RANGES, &range, sizeof(range), outranges, (DWORD)outranges_size, &retbytes, NULL); if (ret == 0 && GetLastError() == ERROR_MORE_DATA) { free(outranges); outranges_size *= 2; outranges = (FILE_ALLOCATED_RANGE_BUFFER *) malloc(outranges_size); if (outranges == NULL) { archive_set_error(&a->archive, ENOMEM, "Couldn't allocate memory"); exit_sts = ARCHIVE_FATAL; goto exit_setup_sparse; } continue; } else break; } if (ret != 0) { if (retbytes > 0) { DWORD i, n; n = retbytes / sizeof(outranges[0]); if (n == 1 && outranges[0].FileOffset.QuadPart == 0 && outranges[0].Length.QuadPart == entry_size) break;/* This is not sparse. */ for (i = 0; i < n; i++) archive_entry_sparse_add_entry(entry, outranges[i].FileOffset.QuadPart, outranges[i].Length.QuadPart); range.FileOffset.QuadPart = outranges[n-1].FileOffset.QuadPart + outranges[n-1].Length.QuadPart; range.Length.QuadPart = entry_size - range.FileOffset.QuadPart; if (range.Length.QuadPart > 0) continue; } else { /* The entire file is a hole. Add one data block of size 0 at the end. */ archive_entry_sparse_add_entry(entry, entry_size, 0); } break; } else { la_dosmaperr(GetLastError()); archive_set_error(&a->archive, errno, "DeviceIoControl Failed: %lu", GetLastError()); exit_sts = ARCHIVE_FAILED; goto exit_setup_sparse; } } exit_setup_sparse: free(outranges); return (exit_sts); } #endif