#include "kvm/disk-image.h" #include "kvm/qcow.h" int debug_iodelay; struct disk_image *disk_image__new(int fd, u64 size, struct disk_image_operations *ops, int use_mmap) { struct disk_image *disk; disk = malloc(sizeof *disk); if (!disk) return NULL; disk->fd = fd; disk->size = size; disk->ops = ops; if (use_mmap == DISK_IMAGE_MMAP) { /* * The write to disk image will be discarded */ disk->priv = mmap(NULL, size, PROT_RW, MAP_PRIVATE | MAP_NORESERVE, fd, 0); if (disk->priv == MAP_FAILED) die("mmap() failed"); } return disk; } struct disk_image *disk_image__open(const char *filename, bool readonly) { struct disk_image *disk; struct stat st; int fd; if (stat(filename, &st) < 0) return NULL; /* blk device ?*/ disk = blkdev__probe(filename, &st); if (disk) return disk; fd = open(filename, readonly ? O_RDONLY : O_RDWR); if (fd < 0) return NULL; /* qcow image ?*/ disk = qcow_probe(fd, true); if (disk) { pr_warning("Forcing read-only support for QCOW"); return disk; } /* raw image ?*/ disk = raw_image__probe(fd, &st, readonly); if (disk) return disk; if (close(fd) < 0) pr_warning("close() failed"); return NULL; } struct disk_image **disk_image__open_all(const char **filenames, bool *readonly, int count) { struct disk_image **disks; int i; if (!count || count > MAX_DISK_IMAGES) return NULL; disks = calloc(count, sizeof(*disks)); if (!disks) return NULL; for (i = 0; i < count; i++) { if (!filenames[i]) continue; disks[i] = disk_image__open(filenames[i], readonly[i]); if (!disks[i]) { pr_error("Loading disk image '%s' failed", filenames[i]); goto error; } } return disks; error: for (i = 0; i < count; i++) disk_image__close(disks[i]); free(disks); return NULL; } int disk_image__flush(struct disk_image *disk) { if (disk->ops->flush) return disk->ops->flush(disk); return fsync(disk->fd); } int disk_image__close(struct disk_image *disk) { /* If there was no disk image then there's nothing to do: */ if (!disk) return 0; if (disk->ops->close) return disk->ops->close(disk); if (close(disk->fd) < 0) pr_warning("close() failed"); free(disk); return 0; } void disk_image__close_all(struct disk_image **disks, int count) { while (count) disk_image__close(disks[--count]); free(disks); } /* * Fill iov with disk data, starting from sector 'sector'. * Return amount of bytes read. */ ssize_t disk_image__read(struct disk_image *disk, u64 sector, const struct iovec *iov, int iovcount) { ssize_t total = 0; if (debug_iodelay) msleep(debug_iodelay); if (disk->ops->read_sector) { total = disk->ops->read_sector(disk, sector, iov, iovcount); if (total < 0) { pr_info("disk_image__read error: total=%ld\n", (long)total); return -1; } } else { die("No disk image operation for read\n"); } return total; } /* * Write iov to disk, starting from sector 'sector'. * Return amount of bytes written. */ ssize_t disk_image__write(struct disk_image *disk, u64 sector, const struct iovec *iov, int iovcount) { ssize_t total = 0; if (debug_iodelay) msleep(debug_iodelay); if (disk->ops->write_sector) { /* * Try writev based operation first */ total = disk->ops->write_sector(disk, sector, iov, iovcount); if (total < 0) { pr_info("disk_image__write error: total=%ld\n", (long)total); return -1; } } else { die("No disk image operation for read\n"); } return total; } ssize_t disk_image__get_serial(struct disk_image *disk, void *buffer, ssize_t *len) { struct stat st; if (fstat(disk->fd, &st) != 0) return 0; *len = snprintf(buffer, *len, "%llu%llu%llu", (u64)st.st_dev, (u64)st.st_rdev, (u64)st.st_ino); return *len; }