/* * windows_io.c --- This is the Windows implementation of the I/O manager. * * Implements a one-block write-through cache. * * Copyright (C) 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001, * 2002 by Theodore Ts'o. * * %Begin-Header% * This file may be redistributed under the terms of the GNU Library * General Public License, version 2. * %End-Header% */ #include #include #include #if !defined(__FreeBSD__) && !defined(__NetBSD__) && !defined(__OpenBSD__) #define _XOPEN_SOURCE 600 #define _DARWIN_C_SOURCE #define _FILE_OFFSET_BITS 64 #ifndef _LARGEFILE_SOURCE #define _LARGEFILE_SOURCE #endif #ifndef _LARGEFILE64_SOURCE #define _LARGEFILE64_SOURCE #endif #ifndef _GNU_SOURCE #define _GNU_SOURCE #endif #endif #include "config.h" #include #include #if HAVE_UNISTD_H #include #endif #if HAVE_ERRNO_H #include #endif #include #include #if HAVE_SYS_TYPES_H #include #endif #define PR_GET_DUMPABLE 3 #if HAVE_SYS_STAT_H #include #endif #include #undef ALIGN_DEBUG //#define DEBUG #ifdef DEBUG #define TRACE(...) {\ char __log[256];\ snprintf(__log, sizeof(__log), __VA_ARGS__);\ __log[sizeof(__log)-1] = 0;\ OutputDebugString(__log);\ } #else #define TRACE(...) do { } while (0); #endif #include "ext2_fs.h" #include "ext2fs.h" #include "ext2fsP.h" /* * For checking structure magic numbers... */ #define EXT2_CHECK_MAGIC(struct, code) \ if ((struct)->magic != (code)) return (code) #define EXT2_CHECK_MAGIC_RETURN(struct, code, ret) \ if ((struct)->magic != (code)) return (ret) #define EXT2_ET_MAGIC_WINDOWS_IO_CHANNEL 0x10ed struct windows_cache { char *buf; unsigned long long block; int access_time; unsigned dirty:1; unsigned in_use:1; }; #define CACHE_SIZE 8 #define WRITE_DIRECT_SIZE 4 /* Must be smaller than CACHE_SIZE */ #define READ_DIRECT_SIZE 4 /* Should be smaller than CACHE_SIZE */ struct windows_private_data { int magic; char name[MAX_PATH]; HANDLE handle; char dos_device[MAX_PATH]; char cf_device[MAX_PATH]; int dev; int flags; int align; int access_time; ext2_loff_t offset; struct windows_cache cache[CACHE_SIZE]; void *bounce; struct struct_io_stats io_stats; }; #define IS_ALIGNED(n, align) ((((uintptr_t) n) & \ ((uintptr_t) ((align)-1))) == 0) static int fake_dos_name_for_device(struct windows_private_data *data) { if (strncmp(data->name, "\\\\", 2) == 0) { data->dos_device[0] = 0; strcpy(data->cf_device, data->name); return 0; } _snprintf(data->dos_device, MAX_PATH, "fakedevice%lu", GetCurrentProcessId()); if (!DefineDosDevice(DDD_RAW_TARGET_PATH, data->dos_device, data->name)) return 1; _snprintf(data->cf_device, MAX_PATH, "\\\\.\\%s", data->dos_device); TRACE("e2fsprogs::fake_dos_name_for_device::DefineDosDevice(\"%s\")", data->dos_device); return 0; } static void remove_fake_dos_name(struct windows_private_data *data) { if (*data->dos_device) { TRACE("e2fsprogs::remove_fake_dos_name::DefineDosDevice(\"%s\")", data->dos_device); DefineDosDevice(DDD_RAW_TARGET_PATH | DDD_EXACT_MATCH_ON_REMOVE | DDD_REMOVE_DEFINITION, data->dos_device, data->name); } } static errcode_t windows_get_stats(io_channel channel, io_stats *stats) { errcode_t retval = 0; struct windows_private_data *data; EXT2_CHECK_MAGIC(channel, EXT2_ET_MAGIC_IO_CHANNEL); data = (struct windows_private_data *) channel->private_data; EXT2_CHECK_MAGIC(data, EXT2_ET_MAGIC_WINDOWS_IO_CHANNEL); if (stats) *stats = &data->io_stats; return retval; } /* * Here are the raw I/O functions */ static errcode_t raw_read_blk(io_channel channel, struct windows_private_data *data, unsigned long long block, int count, void *bufv) { errcode_t retval; ssize_t size; ext2_loff_t location; DWORD actual = 0; unsigned char *buf = bufv; ssize_t really_read = 0; size = (count < 0) ? -count : count * channel->block_size; data->io_stats.bytes_read += size; location = ((ext2_loff_t) block * channel->block_size) + data->offset; if (data->flags & IO_FLAG_FORCE_BOUNCE) { if (SetFilePointer(data->handle, location, NULL, FILE_BEGIN) == INVALID_SET_FILE_POINTER) { retval = GetLastError(); goto error_out; } goto bounce_read; } if (SetFilePointer(data->handle, location, NULL, FILE_BEGIN) == INVALID_SET_FILE_POINTER) { retval = GetLastError(); goto error_out; } if ((channel->align == 0) || (IS_ALIGNED(buf, channel->align) && IS_ALIGNED(size, channel->align))) { if (!ReadFile(data->handle, buf, size, &actual, NULL)) { retval = GetLastError(); goto error_out; } if (actual != size) { short_read: if (actual < 0) { retval = GetLastError(); actual = 0; } else retval = EXT2_ET_SHORT_READ; goto error_out; } return 0; } /* * The buffer or size which we're trying to read isn't aligned * to the O_DIRECT rules, so we need to do this the hard way... */ bounce_read: while (size > 0) { if (!ReadFile(data->handle, data->bounce, channel->block_size, &actual, NULL)) { retval = GetLastError(); goto error_out; } if (actual != channel->block_size) { actual = really_read; buf -= really_read; size += really_read; goto short_read; } actual = size; if (size > channel->block_size) actual = channel->block_size; memcpy(buf, data->bounce, actual); really_read += actual; size -= actual; buf += actual; } return 0; error_out: if (actual >= 0 && actual < size) memset((char *) buf+actual, 0, size-actual); if (channel->read_error) retval = (channel->read_error)(channel, block, count, buf, size, actual, retval); return retval; } static errcode_t raw_write_blk(io_channel channel, struct windows_private_data *data, unsigned long long block, int count, const void *bufv) { ssize_t size; ext2_loff_t location; DWORD actual = 0; errcode_t retval; const unsigned char *buf = bufv; if (count == 1) size = channel->block_size; else { if (count < 0) size = -count; else size = count * channel->block_size; } data->io_stats.bytes_written += size; location = ((ext2_loff_t) block * channel->block_size) + data->offset; if (data->flags & IO_FLAG_FORCE_BOUNCE) { if (SetFilePointer(data->handle, location, NULL, FILE_BEGIN) == INVALID_SET_FILE_POINTER) { retval = GetLastError(); goto error_out; } goto bounce_write; } if (SetFilePointer(data->handle, location, NULL, FILE_BEGIN) == INVALID_SET_FILE_POINTER) { retval = GetLastError(); goto error_out; } SetLastError(0); if ((channel->align == 0) || (IS_ALIGNED(buf, channel->align) && IS_ALIGNED(size, channel->align))) { if (!WriteFile(data->handle, buf, size, &actual, NULL)) { retval = GetLastError(); goto error_out; } if (actual != size) { short_write: retval = EXT2_ET_SHORT_WRITE; goto error_out; } return 0; } /* * The buffer or size which we're trying to write isn't aligned * to the O_DIRECT rules, so we need to do this the hard way... */ bounce_write: while (size > 0) { if (size < channel->block_size) { if (!ReadFile(data->handle, data->bounce, channel->block_size, &actual, NULL)) { retval = GetLastError(); goto error_out; } if (actual != channel->block_size) { if (actual < 0) { retval = GetLastError(); goto error_out; } memset((char *) data->bounce + actual, 0, channel->block_size - actual); } } actual = size; if (size > channel->block_size) actual = channel->block_size; memcpy(data->bounce, buf, actual); if (SetFilePointer(data->handle, location, NULL, FILE_BEGIN) == INVALID_SET_FILE_POINTER) { retval = GetLastError(); goto error_out; } if (!WriteFile(data->handle, data->bounce, channel->block_size, &actual, NULL)) { retval = GetLastError(); goto error_out; } if (actual != channel->block_size) goto short_write; size -= actual; buf += actual; location += actual; } return 0; error_out: if (channel->write_error) retval = (channel->write_error)(channel, block, count, buf, size, actual, retval); return retval; } /* * Here we implement the cache functions */ /* Allocate the cache buffers */ static errcode_t alloc_cache(io_channel channel, struct windows_private_data *data) { errcode_t retval; struct windows_cache *cache; int i; data->access_time = 0; for (i=0, cache = data->cache; i < CACHE_SIZE; i++, cache++) { cache->block = 0; cache->access_time = 0; cache->dirty = 0; cache->in_use = 0; if (cache->buf) ext2fs_free_mem(&cache->buf); retval = io_channel_alloc_buf(channel, 0, &cache->buf); if (retval) return retval; } if (channel->align || data->flags & IO_FLAG_FORCE_BOUNCE) { if (data->bounce) ext2fs_free_mem(&data->bounce); retval = io_channel_alloc_buf(channel, 0, &data->bounce); } return retval; } /* Free the cache buffers */ static void free_cache(struct windows_private_data *data) { struct windows_cache *cache; int i; data->access_time = 0; for (i=0, cache = data->cache; i < CACHE_SIZE; i++, cache++) { cache->block = 0; cache->access_time = 0; cache->dirty = 0; cache->in_use = 0; if (cache->buf) ext2fs_free_mem(&cache->buf); } if (data->bounce) ext2fs_free_mem(&data->bounce); } #ifndef NO_IO_CACHE /* * Try to find a block in the cache. If the block is not found, and * eldest is a non-zero pointer, then fill in eldest with the cache * entry to that should be reused. */ static struct windows_cache *find_cached_block(struct windows_private_data *data, unsigned long long block, struct windows_cache **eldest) { struct windows_cache *cache, *unused_cache, *oldest_cache; int i; unused_cache = oldest_cache = 0; for (i=0, cache = data->cache; i < CACHE_SIZE; i++, cache++) { if (!cache->in_use) { if (!unused_cache) unused_cache = cache; continue; } if (cache->block == block) { cache->access_time = ++data->access_time; return cache; } if (!oldest_cache || (cache->access_time < oldest_cache->access_time)) oldest_cache = cache; } if (eldest) *eldest = (unused_cache) ? unused_cache : oldest_cache; return 0; } /* * Reuse a particular cache entry for another block. */ static void reuse_cache(io_channel channel, struct windows_private_data *data, struct windows_cache *cache, unsigned long long block) { if (cache->dirty && cache->in_use) raw_write_blk(channel, data, cache->block, 1, cache->buf); cache->in_use = 1; cache->dirty = 0; cache->block = block; cache->access_time = ++data->access_time; } /* * Flush all of the blocks in the cache */ static errcode_t flush_cached_blocks(io_channel channel, struct windows_private_data *data, int invalidate) { struct windows_cache *cache; errcode_t retval, retval2; int i; retval2 = 0; for (i=0, cache = data->cache; i < CACHE_SIZE; i++, cache++) { if (!cache->in_use) continue; if (invalidate) cache->in_use = 0; if (!cache->dirty) continue; retval = raw_write_blk(channel, data, cache->block, 1, cache->buf); if (retval) retval2 = retval; else cache->dirty = 0; } return retval2; } #endif /* NO_IO_CACHE */ static errcode_t windows_open_channel(struct windows_private_data *data, int flags, io_channel *channel, io_manager io_mgr) { io_channel io = NULL; errcode_t retval; ext2fs_struct_stat st; retval = ext2fs_get_mem(sizeof(struct struct_io_channel), &io); if (retval) goto cleanup; memset(io, 0, sizeof(struct struct_io_channel)); io->magic = EXT2_ET_MAGIC_IO_CHANNEL; io->manager = io_mgr; retval = ext2fs_get_mem(strlen(data->name)+1, &io->name); if (retval) goto cleanup; strcpy(io->name, data->name); io->private_data = data; io->block_size = 1024; io->read_error = 0; io->write_error = 0; io->refcount = 1; #if defined(O_DIRECT) if (flags & IO_FLAG_DIRECT_IO) io->align = ext2fs_get_dio_alignment(data->dev); #endif /* * If the device is really a block device, then set the * appropriate flag, otherwise we can set DISCARD_ZEROES flag * because we are going to use punch hole instead of discard * and if it succeed, subsequent read from sparse area returns * zero. */ if (ext2fs_fstat(data->dev, &st) == 0) { if (ext2fsP_is_disk_device(st.st_mode)) io->flags |= CHANNEL_FLAGS_BLOCK_DEVICE; else io->flags |= CHANNEL_FLAGS_DISCARD_ZEROES; } if ((retval = alloc_cache(io, data))) goto cleanup; #ifdef BLKROGET if (flags & IO_FLAG_RW) { int error; int readonly = 0; /* Is the block device actually writable? */ error = ioctl(data->dev, BLKROGET, &readonly); if (!error && readonly) { retval = EPERM; goto cleanup; } } #endif *channel = io; return 0; cleanup: if (data) { if (data->dev >= 0) close(data->dev); free_cache(data); ext2fs_free_mem(&data); } if (io) { if (io->name) { ext2fs_free_mem(&io->name); } ext2fs_free_mem(&io); } return retval; } static DWORD windows_open_device(struct windows_private_data *data, int open_flags) { DWORD ret = 0; if (*data->name != '\\') strcpy(data->cf_device, data->name); else if (fake_dos_name_for_device(data)) return -1; DWORD desired_access = GENERIC_READ | ((open_flags & O_RDWR) ? GENERIC_WRITE : 0); DWORD share_mode = (open_flags & O_EXCL) ? 0 : FILE_SHARE_READ | ((open_flags & O_RDWR) ? FILE_SHARE_WRITE : 0); DWORD flags_and_attributes = #if defined(O_DIRECT) (open_flags & O_DIRECT) ? (FILE_FLAG_NO_BUFFERING | FILE_FLAG_WRITE_THROUGH) : FILE_ATTRIBUTE_NORMAL; #else FILE_FLAG_NO_BUFFERING | FILE_FLAG_WRITE_THROUGH; #endif data->handle = CreateFile(data->cf_device, desired_access, share_mode, NULL, OPEN_EXISTING, flags_and_attributes, NULL); if (data->handle == INVALID_HANDLE_VALUE) { ret = GetLastError(); goto invalid_handle; } TRACE("e2fsprogs::windows_open_device::CreateFile(\"%s\") = %p", data->cf_device, data->handle); data->dev = _open_osfhandle((intptr_t)data->handle, 0); if (data->dev < 0) { ret = GetLastError() ? GetLastError() : 9999; goto osfhandle_error; } TRACE("e2fsprogs::windows_open_device::_open_osfhandle(%p) = %d", data->handle, data->dev); return 0; osfhandle_error: TRACE("e2fsprogs::windows_open_device::CloseHandle(%p)", data->handle); CloseHandle(data->handle); invalid_handle: remove_fake_dos_name(data); TRACE("e2fsprogs::windows_open_device() = %lu, errno = %d", ret, errno); return ret; } static struct windows_private_data *init_private_data(const char *name, int flags) { struct windows_private_data *data = NULL; if (ext2fs_get_mem(sizeof(struct windows_private_data), &data)) return NULL; memset(data, 0, sizeof(struct windows_private_data)); strncpy(data->name, name, sizeof(data->name) - 1); data->magic = EXT2_ET_MAGIC_WINDOWS_IO_CHANNEL; data->io_stats.num_fields = 2; data->flags = flags; data->handle = INVALID_HANDLE_VALUE; return data; } static errcode_t windows_open(const char *name, int flags, io_channel *channel) { int open_flags; struct windows_private_data *data; if (name == 0) return EXT2_ET_BAD_DEVICE_NAME; data = init_private_data(name, flags); if (!data) return EXT2_ET_NO_MEMORY; open_flags = (flags & IO_FLAG_RW) ? O_RDWR : O_RDONLY; if (flags & IO_FLAG_EXCLUSIVE) open_flags |= O_EXCL; #if defined(O_DIRECT) if (flags & IO_FLAG_DIRECT_IO) open_flags |= O_DIRECT; #endif if (windows_open_device(data, open_flags)) { ext2fs_free_mem(&data); return EXT2_ET_BAD_DEVICE_NAME; } return windows_open_channel(data, flags, channel, windows_io_manager); } static errcode_t windows_close(io_channel channel) { struct windows_private_data *data; errcode_t retval = 0; EXT2_CHECK_MAGIC(channel, EXT2_ET_MAGIC_IO_CHANNEL); data = (struct windows_private_data *) channel->private_data; EXT2_CHECK_MAGIC(data, EXT2_ET_MAGIC_WINDOWS_IO_CHANNEL); if (--channel->refcount > 0) return 0; #ifndef NO_IO_CACHE retval = flush_cached_blocks(channel, data, 0); #endif remove_fake_dos_name(data); if (_close(data->dev) != 0) retval = errno; TRACE("e2fsprogs::windows_close::_close(%d)", data->dev); free_cache(data); ext2fs_free_mem(&channel->private_data); if (channel->name) ext2fs_free_mem(&channel->name); ext2fs_free_mem(&channel); return retval; } static errcode_t windows_set_blksize(io_channel channel, int blksize) { struct windows_private_data *data; errcode_t retval; EXT2_CHECK_MAGIC(channel, EXT2_ET_MAGIC_IO_CHANNEL); data = (struct windows_private_data *) channel->private_data; EXT2_CHECK_MAGIC(data, EXT2_ET_MAGIC_WINDOWS_IO_CHANNEL); if (channel->block_size != blksize) { #ifndef NO_IO_CACHE if ((retval = flush_cached_blocks(channel, data, 0))) return retval; #endif channel->block_size = blksize; free_cache(data); if ((retval = alloc_cache(channel, data))) return retval; } return 0; } static errcode_t windows_read_blk64(io_channel channel, unsigned long long block, int count, void *buf) { struct windows_private_data *data; struct windows_cache *cache, *reuse[READ_DIRECT_SIZE]; errcode_t retval; char *cp; int i, j; EXT2_CHECK_MAGIC(channel, EXT2_ET_MAGIC_IO_CHANNEL); data = (struct windows_private_data *) channel->private_data; EXT2_CHECK_MAGIC(data, EXT2_ET_MAGIC_WINDOWS_IO_CHANNEL); #ifdef NO_IO_CACHE return raw_read_blk(channel, data, block, count, buf); #else /* * If we're doing an odd-sized read or a very large read, * flush out the cache and then do a direct read. */ if (count < 0 || count > WRITE_DIRECT_SIZE) { if ((retval = flush_cached_blocks(channel, data, 0))) return retval; return raw_read_blk(channel, data, block, count, buf); } cp = buf; while (count > 0) { /* If it's in the cache, use it! */ if ((cache = find_cached_block(data, block, &reuse[0]))) { #ifdef DEBUG printf("Using cached block %lu\n", block); #endif memcpy(cp, cache->buf, channel->block_size); count--; block++; cp += channel->block_size; continue; } if (count == 1) { /* * Special case where we read directly into the * cache buffer; important in the O_DIRECT case */ cache = reuse[0]; reuse_cache(channel, data, cache, block); if ((retval = raw_read_blk(channel, data, block, 1, cache->buf))) { cache->in_use = 0; return retval; } memcpy(cp, cache->buf, channel->block_size); return 0; } /* * Find the number of uncached blocks so we can do a * single read request */ for (i=1; i < count; i++) if (find_cached_block(data, block+i, &reuse[i])) break; #ifdef DEBUG printf("Reading %d blocks starting at %lu\n", i, block); #endif if ((retval = raw_read_blk(channel, data, block, i, cp))) return retval; /* Save the results in the cache */ for (j=0; j < i; j++) { count--; cache = reuse[j]; reuse_cache(channel, data, cache, block++); memcpy(cache->buf, cp, channel->block_size); cp += channel->block_size; } } return 0; #endif /* NO_IO_CACHE */ } static errcode_t windows_read_blk(io_channel channel, unsigned long block, int count, void *buf) { return windows_read_blk64(channel, block, count, buf); } static errcode_t windows_write_blk64(io_channel channel, unsigned long long block, int count, const void *buf) { struct windows_private_data *data; struct windows_cache *cache, *reuse; errcode_t retval = 0; const char *cp; int writethrough; EXT2_CHECK_MAGIC(channel, EXT2_ET_MAGIC_IO_CHANNEL); data = (struct windows_private_data *) channel->private_data; EXT2_CHECK_MAGIC(data, EXT2_ET_MAGIC_WINDOWS_IO_CHANNEL); #ifdef NO_IO_CACHE return raw_write_blk(channel, data, block, count, buf); #else /* * If we're doing an odd-sized write or a very large write, * flush out the cache completely and then do a direct write. */ if (count < 0 || count > WRITE_DIRECT_SIZE) { if ((retval = flush_cached_blocks(channel, data, 1))) return retval; return raw_write_blk(channel, data, block, count, buf); } /* * For a moderate-sized multi-block write, first force a write * if we're in write-through cache mode, and then fill the * cache with the blocks. */ writethrough = channel->flags & CHANNEL_FLAGS_WRITETHROUGH; if (writethrough) retval = raw_write_blk(channel, data, block, count, buf); cp = buf; while (count > 0) { cache = find_cached_block(data, block, &reuse); if (!cache) { cache = reuse; reuse_cache(channel, data, cache, block); } if (cache->buf != cp) memcpy(cache->buf, cp, channel->block_size); cache->dirty = !writethrough; count--; block++; cp += channel->block_size; } return retval; #endif /* NO_IO_CACHE */ } static errcode_t windows_cache_readahead(io_channel channel, unsigned long long block, unsigned long long count) { return EXT2_ET_OP_NOT_SUPPORTED; } static errcode_t windows_write_blk(io_channel channel, unsigned long block, int count, const void *buf) { return windows_write_blk64(channel, block, count, buf); } static errcode_t windows_write_byte(io_channel channel, unsigned long offset, int size, const void *buf) { return EXT2_ET_UNIMPLEMENTED; } HANDLE windows_get_handle(io_channel channel) { struct windows_private_data *data; EXT2_CHECK_MAGIC_RETURN(channel, EXT2_ET_MAGIC_IO_CHANNEL, INVALID_HANDLE_VALUE); data = (struct windows_private_data *) channel->private_data; EXT2_CHECK_MAGIC_RETURN(data, EXT2_ET_MAGIC_WINDOWS_IO_CHANNEL, INVALID_HANDLE_VALUE); return data->handle; } /* * Flush data buffers to disk. */ static errcode_t windows_flush(io_channel channel) { struct windows_private_data *data; errcode_t retval = 0; EXT2_CHECK_MAGIC(channel, EXT2_ET_MAGIC_IO_CHANNEL); data = (struct windows_private_data *) channel->private_data; EXT2_CHECK_MAGIC(data, EXT2_ET_MAGIC_WINDOWS_IO_CHANNEL); #ifndef NO_IO_CACHE retval = flush_cached_blocks(channel, data, 0); #endif return retval; } static errcode_t windows_set_option(io_channel channel, const char *option, const char *arg) { struct windows_private_data *data; unsigned long long tmp; char *end; EXT2_CHECK_MAGIC(channel, EXT2_ET_MAGIC_IO_CHANNEL); data = (struct windows_private_data *) channel->private_data; EXT2_CHECK_MAGIC(data, EXT2_ET_MAGIC_WINDOWS_IO_CHANNEL); if (!strcmp(option, "offset")) { if (!arg) return EXT2_ET_INVALID_ARGUMENT; tmp = strtoull(arg, &end, 0); if (*end) return EXT2_ET_INVALID_ARGUMENT; data->offset = tmp; if (data->offset < 0) return EXT2_ET_INVALID_ARGUMENT; return 0; } return EXT2_ET_INVALID_ARGUMENT; } static errcode_t windows_discard(io_channel channel, unsigned long long block, unsigned long long count) { TRACE("e2fsprogs::windows_discard::EXT2_ET_UNIMPLEMENTED"); return EXT2_ET_UNIMPLEMENTED; } /* parameters might not be used if OS doesn't support zeroout */ #if __GNUC_PREREQ (4, 6) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wunused-parameter" #endif static errcode_t windows_zeroout(io_channel channel, unsigned long long block, unsigned long long count) { struct windows_private_data *data; int ret; EXT2_CHECK_MAGIC(channel, EXT2_ET_MAGIC_IO_CHANNEL); data = (struct windows_private_data *) channel->private_data; EXT2_CHECK_MAGIC(data, EXT2_ET_MAGIC_WINDOWS_IO_CHANNEL); if (channel->flags & CHANNEL_FLAGS_BLOCK_DEVICE) { /* Not implemented until the BLKZEROOUT mess is fixed */ goto unimplemented; } else { /* Regular file, try to use truncate/punch/zero. */ struct stat statbuf; if (count == 0) return 0; /* * If we're trying to zero a range past the end of the file, * extend the file size, then truncate everything. */ ret = fstat(data->dev, &statbuf); if (ret) goto err; if ((unsigned long long) statbuf.st_size < (block + count) * channel->block_size + data->offset) { ret = ftruncate(data->dev, (block + count) * channel->block_size + data->offset); if (ret) goto err; } goto unimplemented; } err: if (ret < 0) { if (errno == EOPNOTSUPP) goto unimplemented; return errno; } return 0; unimplemented: return EXT2_ET_UNIMPLEMENTED; } int ext2fs_open_file(const char *pathname, int flags, mode_t mode) { flags |= O_BINARY; if (mode) #if defined(HAVE_OPEN64) && !defined(__OSX_AVAILABLE_BUT_DEPRECATED) return open64(pathname, flags, mode); else return open64(pathname, flags); #else return open(pathname, flags, mode); else return open(pathname, flags); #endif } int ext2fs_stat(const char *path, ext2fs_struct_stat *buf) { #if defined(HAVE_FSTAT64) && !defined(__OSX_AVAILABLE_BUT_DEPRECATED) return stat64(path, buf); #else return stat(path, buf); #endif } int ext2fs_fstat(int fd, ext2fs_struct_stat *buf) { #if defined(HAVE_FSTAT64) && !defined(__OSX_AVAILABLE_BUT_DEPRECATED) return fstat64(fd, buf); #else return fstat(fd, buf); #endif } #if __GNUC_PREREQ (4, 6) #pragma GCC diagnostic pop #endif static struct struct_io_manager struct_windows_manager = { .magic = EXT2_ET_MAGIC_IO_MANAGER, .name = "Windows I/O Manager", .open = windows_open, .close = windows_close, .set_blksize = windows_set_blksize, .read_blk = windows_read_blk, .write_blk = windows_write_blk, .flush = windows_flush, .write_byte = windows_write_byte, .set_option = windows_set_option, .get_stats = windows_get_stats, .read_blk64 = windows_read_blk64, .write_blk64 = windows_write_blk64, .discard = windows_discard, .cache_readahead = windows_cache_readahead, .zeroout = windows_zeroout, }; io_manager windows_io_manager = &struct_windows_manager;