/* * Copyright (C) 2018 Western Digital Corporation or its affiliates. * * This file is released under the GPL. */ #include #include #include #include #include #include #include #include #include #include "file.h" #include "fio.h" #include "lib/pow2.h" #include "log.h" #include "smalloc.h" #include "verify.h" #include "zbd.h" /** * zbd_zone_idx - convert an offset into a zone number * @f: file pointer. * @offset: offset in bytes. If this offset is in the first zone_size bytes * past the disk size then the index of the sentinel is returned. */ static uint32_t zbd_zone_idx(const struct fio_file *f, uint64_t offset) { uint32_t zone_idx; if (f->zbd_info->zone_size_log2 > 0) zone_idx = offset >> f->zbd_info->zone_size_log2; else zone_idx = offset / f->zbd_info->zone_size; return min(zone_idx, f->zbd_info->nr_zones); } /** * zbd_zone_full - verify whether a minimum number of bytes remain in a zone * @f: file pointer. * @z: zone info pointer. * @required: minimum number of bytes that must remain in a zone. * * The caller must hold z->mutex. */ static bool zbd_zone_full(const struct fio_file *f, struct fio_zone_info *z, uint64_t required) { assert((required & 511) == 0); return z->type == BLK_ZONE_TYPE_SEQWRITE_REQ && z->wp + required > z->start + f->zbd_info->zone_size; } static bool is_valid_offset(const struct fio_file *f, uint64_t offset) { return (uint64_t)(offset - f->file_offset) < f->io_size; } /* Verify whether direct I/O is used for all host-managed zoned drives. */ static bool zbd_using_direct_io(void) { struct thread_data *td; struct fio_file *f; int i, j; for_each_td(td, i) { if (td->o.odirect || !(td->o.td_ddir & TD_DDIR_WRITE)) continue; for_each_file(td, f, j) { if (f->zbd_info && f->zbd_info->model == ZBD_DM_HOST_MANAGED) return false; } } return true; } /* Whether or not the I/O range for f includes one or more sequential zones */ static bool zbd_is_seq_job(struct fio_file *f) { uint32_t zone_idx, zone_idx_b, zone_idx_e; assert(f->zbd_info); if (f->io_size == 0) return false; zone_idx_b = zbd_zone_idx(f, f->file_offset); zone_idx_e = zbd_zone_idx(f, f->file_offset + f->io_size - 1); for (zone_idx = zone_idx_b; zone_idx <= zone_idx_e; zone_idx++) if (f->zbd_info->zone_info[zone_idx].type == BLK_ZONE_TYPE_SEQWRITE_REQ) return true; return false; } /* * Verify whether offset and size parameters are aligned with zone boundaries. */ static bool zbd_verify_sizes(void) { const struct fio_zone_info *z; struct thread_data *td; struct fio_file *f; uint64_t new_offset, new_end; uint32_t zone_idx; int i, j; for_each_td(td, i) { for_each_file(td, f, j) { if (!f->zbd_info) continue; if (f->file_offset >= f->real_file_size) continue; if (!zbd_is_seq_job(f)) continue; zone_idx = zbd_zone_idx(f, f->file_offset); z = &f->zbd_info->zone_info[zone_idx]; if (f->file_offset != z->start) { new_offset = (z+1)->start; if (new_offset >= f->file_offset + f->io_size) { log_info("%s: io_size must be at least one zone\n", f->file_name); return false; } log_info("%s: rounded up offset from %lu to %lu\n", f->file_name, f->file_offset, new_offset); f->io_size -= (new_offset - f->file_offset); f->file_offset = new_offset; } zone_idx = zbd_zone_idx(f, f->file_offset + f->io_size); z = &f->zbd_info->zone_info[zone_idx]; new_end = z->start; if (f->file_offset + f->io_size != new_end) { if (new_end <= f->file_offset) { log_info("%s: io_size must be at least one zone\n", f->file_name); return false; } log_info("%s: rounded down io_size from %lu to %lu\n", f->file_name, f->io_size, new_end - f->file_offset); f->io_size = new_end - f->file_offset; } } } return true; } static bool zbd_verify_bs(void) { struct thread_data *td; struct fio_file *f; uint32_t zone_size; int i, j, k; for_each_td(td, i) { for_each_file(td, f, j) { if (!f->zbd_info) continue; zone_size = f->zbd_info->zone_size; for (k = 0; k < ARRAY_SIZE(td->o.bs); k++) { if (td->o.verify != VERIFY_NONE && zone_size % td->o.bs[k] != 0) { log_info("%s: block size %llu is not a divisor of the zone size %d\n", f->file_name, td->o.bs[k], zone_size); return false; } } } } return true; } /* * Read zone information into @buf starting from sector @start_sector. * @fd is a file descriptor that refers to a block device and @bufsz is the * size of @buf. * * Returns 0 upon success and a negative error code upon failure. */ static int read_zone_info(int fd, uint64_t start_sector, void *buf, unsigned int bufsz) { struct blk_zone_report *hdr = buf; if (bufsz < sizeof(*hdr)) return -EINVAL; memset(hdr, 0, sizeof(*hdr)); hdr->nr_zones = (bufsz - sizeof(*hdr)) / sizeof(struct blk_zone); hdr->sector = start_sector; return ioctl(fd, BLKREPORTZONE, hdr) >= 0 ? 0 : -errno; } /* * Read up to 255 characters from the first line of a file. Strip the trailing * newline. */ static char *read_file(const char *path) { char line[256], *p = line; FILE *f; f = fopen(path, "rb"); if (!f) return NULL; if (!fgets(line, sizeof(line), f)) line[0] = '\0'; strsep(&p, "\n"); fclose(f); return strdup(line); } static enum blk_zoned_model get_zbd_model(const char *file_name) { enum blk_zoned_model model = ZBD_DM_NONE; char *zoned_attr_path = NULL; char *model_str = NULL; struct stat statbuf; if (stat(file_name, &statbuf) < 0) goto out; if (asprintf(&zoned_attr_path, "/sys/dev/block/%d:%d/queue/zoned", major(statbuf.st_rdev), minor(statbuf.st_rdev)) < 0) goto out; model_str = read_file(zoned_attr_path); if (!model_str) goto out; dprint(FD_ZBD, "%s: zbd model string: %s\n", file_name, model_str); if (strcmp(model_str, "host-aware") == 0) model = ZBD_DM_HOST_AWARE; else if (strcmp(model_str, "host-managed") == 0) model = ZBD_DM_HOST_MANAGED; out: free(model_str); free(zoned_attr_path); return model; } static int ilog2(uint64_t i) { int log = -1; while (i) { i >>= 1; log++; } return log; } /* * Initialize f->zbd_info for devices that are not zoned block devices. This * allows to execute a ZBD workload against a non-ZBD device. */ static int init_zone_info(struct thread_data *td, struct fio_file *f) { uint32_t nr_zones; struct fio_zone_info *p; uint64_t zone_size; struct zoned_block_device_info *zbd_info = NULL; pthread_mutexattr_t attr; int i; zone_size = td->o.zone_size; assert(zone_size); nr_zones = (f->real_file_size + zone_size - 1) / zone_size; zbd_info = scalloc(1, sizeof(*zbd_info) + (nr_zones + 1) * sizeof(zbd_info->zone_info[0])); if (!zbd_info) return -ENOMEM; pthread_mutexattr_init(&attr); pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_RECURSIVE); pthread_mutexattr_setpshared(&attr, true); pthread_mutex_init(&zbd_info->mutex, &attr); zbd_info->refcount = 1; p = &zbd_info->zone_info[0]; for (i = 0; i < nr_zones; i++, p++) { pthread_mutex_init(&p->mutex, &attr); p->start = i * zone_size; p->wp = p->start + zone_size; p->type = BLK_ZONE_TYPE_SEQWRITE_REQ; p->cond = BLK_ZONE_COND_EMPTY; } /* a sentinel */ p->start = nr_zones * zone_size; f->zbd_info = zbd_info; f->zbd_info->zone_size = zone_size; f->zbd_info->zone_size_log2 = is_power_of_2(zone_size) ? ilog2(zone_size) : -1; f->zbd_info->nr_zones = nr_zones; pthread_mutexattr_destroy(&attr); return 0; } /* * Parse the BLKREPORTZONE output and store it in f->zbd_info. Must be called * only for devices that support this ioctl, namely zoned block devices. */ static int parse_zone_info(struct thread_data *td, struct fio_file *f) { const unsigned int bufsz = sizeof(struct blk_zone_report) + 4096 * sizeof(struct blk_zone); uint32_t nr_zones; struct blk_zone_report *hdr; const struct blk_zone *z; struct fio_zone_info *p; uint64_t zone_size, start_sector; struct zoned_block_device_info *zbd_info = NULL; pthread_mutexattr_t attr; void *buf; int fd, i, j, ret = 0; pthread_mutexattr_init(&attr); pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_RECURSIVE); pthread_mutexattr_setpshared(&attr, true); buf = malloc(bufsz); if (!buf) goto out; fd = open(f->file_name, O_RDONLY | O_LARGEFILE); if (fd < 0) { ret = -errno; goto free; } ret = read_zone_info(fd, 0, buf, bufsz); if (ret < 0) { log_info("fio: BLKREPORTZONE(%lu) failed for %s (%d).\n", 0UL, f->file_name, -ret); goto close; } hdr = buf; if (hdr->nr_zones < 1) { log_info("fio: %s has invalid zone information.\n", f->file_name); goto close; } z = (void *)(hdr + 1); zone_size = z->len << 9; nr_zones = (f->real_file_size + zone_size - 1) / zone_size; if (td->o.zone_size == 0) { td->o.zone_size = zone_size; } else if (td->o.zone_size != zone_size) { log_info("fio: %s job parameter zonesize %lld does not match disk zone size %ld.\n", f->file_name, td->o.zone_size, zone_size); ret = -EINVAL; goto close; } dprint(FD_ZBD, "Device %s has %d zones of size %lu KB\n", f->file_name, nr_zones, zone_size / 1024); zbd_info = scalloc(1, sizeof(*zbd_info) + (nr_zones + 1) * sizeof(zbd_info->zone_info[0])); ret = -ENOMEM; if (!zbd_info) goto close; pthread_mutex_init(&zbd_info->mutex, &attr); zbd_info->refcount = 1; p = &zbd_info->zone_info[0]; for (start_sector = 0, j = 0; j < nr_zones;) { z = (void *)(hdr + 1); for (i = 0; i < hdr->nr_zones; i++, j++, z++, p++) { pthread_mutex_init(&p->mutex, &attr); p->start = z->start << 9; switch (z->cond) { case BLK_ZONE_COND_NOT_WP: p->wp = p->start; break; case BLK_ZONE_COND_FULL: p->wp = p->start + zone_size; break; default: assert(z->start <= z->wp); assert(z->wp <= z->start + (zone_size >> 9)); p->wp = z->wp << 9; break; } p->type = z->type; p->cond = z->cond; if (j > 0 && p->start != p[-1].start + zone_size) { log_info("%s: invalid zone data\n", f->file_name); ret = -EINVAL; goto close; } } z--; start_sector = z->start + z->len; if (j >= nr_zones) break; ret = read_zone_info(fd, start_sector, buf, bufsz); if (ret < 0) { log_info("fio: BLKREPORTZONE(%lu) failed for %s (%d).\n", start_sector, f->file_name, -ret); goto close; } } /* a sentinel */ zbd_info->zone_info[nr_zones].start = start_sector << 9; f->zbd_info = zbd_info; f->zbd_info->zone_size = zone_size; f->zbd_info->zone_size_log2 = is_power_of_2(zone_size) ? ilog2(zone_size) : -1; f->zbd_info->nr_zones = nr_zones; zbd_info = NULL; ret = 0; close: sfree(zbd_info); close(fd); free: free(buf); out: pthread_mutexattr_destroy(&attr); return ret; } /* * Allocate zone information and store it into f->zbd_info if zonemode=zbd. * * Returns 0 upon success and a negative error code upon failure. */ int zbd_create_zone_info(struct thread_data *td, struct fio_file *f) { enum blk_zoned_model zbd_model; int ret = 0; assert(td->o.zone_mode == ZONE_MODE_ZBD); zbd_model = get_zbd_model(f->file_name); switch (zbd_model) { case ZBD_DM_HOST_AWARE: case ZBD_DM_HOST_MANAGED: ret = parse_zone_info(td, f); break; case ZBD_DM_NONE: ret = init_zone_info(td, f); break; } if (ret == 0) f->zbd_info->model = zbd_model; return ret; } void zbd_free_zone_info(struct fio_file *f) { uint32_t refcount; if (!f->zbd_info) return; pthread_mutex_lock(&f->zbd_info->mutex); refcount = --f->zbd_info->refcount; pthread_mutex_unlock(&f->zbd_info->mutex); assert((int32_t)refcount >= 0); if (refcount == 0) sfree(f->zbd_info); f->zbd_info = NULL; } /* * Initialize f->zbd_info. * * Returns 0 upon success and a negative error code upon failure. * * Note: this function can only work correctly if it is called before the first * fio fork() call. */ static int zbd_init_zone_info(struct thread_data *td, struct fio_file *file) { struct thread_data *td2; struct fio_file *f2; int i, j, ret; for_each_td(td2, i) { for_each_file(td2, f2, j) { if (td2 == td && f2 == file) continue; if (!f2->zbd_info || strcmp(f2->file_name, file->file_name) != 0) continue; file->zbd_info = f2->zbd_info; file->zbd_info->refcount++; return 0; } } ret = zbd_create_zone_info(td, file); if (ret < 0) td_verror(td, -ret, "BLKREPORTZONE failed"); return ret; } int zbd_init(struct thread_data *td) { struct fio_file *f; int i; for_each_file(td, f, i) { if (f->filetype != FIO_TYPE_BLOCK) continue; if (td->o.zone_size && td->o.zone_size < 512) { log_err("%s: zone size must be at least 512 bytes for --zonemode=zbd\n\n", f->file_name); return 1; } if (td->o.zone_size == 0 && get_zbd_model(f->file_name) == ZBD_DM_NONE) { log_err("%s: Specifying the zone size is mandatory for regular block devices with --zonemode=zbd\n\n", f->file_name); return 1; } zbd_init_zone_info(td, f); } if (!zbd_using_direct_io()) { log_err("Using direct I/O is mandatory for writing to ZBD drives\n\n"); return 1; } if (!zbd_verify_sizes()) return 1; if (!zbd_verify_bs()) return 1; return 0; } /** * zbd_reset_range - reset zones for a range of sectors * @td: FIO thread data. * @f: Fio file for which to reset zones * @sector: Starting sector in units of 512 bytes * @nr_sectors: Number of sectors in units of 512 bytes * * Returns 0 upon success and a negative error code upon failure. */ static int zbd_reset_range(struct thread_data *td, const struct fio_file *f, uint64_t offset, uint64_t length) { struct blk_zone_range zr = { .sector = offset >> 9, .nr_sectors = length >> 9, }; uint32_t zone_idx_b, zone_idx_e; struct fio_zone_info *zb, *ze, *z; int ret = 0; assert(f->fd != -1); assert(is_valid_offset(f, offset + length - 1)); switch (f->zbd_info->model) { case ZBD_DM_HOST_AWARE: case ZBD_DM_HOST_MANAGED: ret = ioctl(f->fd, BLKRESETZONE, &zr); if (ret < 0) { td_verror(td, errno, "resetting wp failed"); log_err("%s: resetting wp for %llu sectors at sector %llu failed (%d).\n", f->file_name, zr.nr_sectors, zr.sector, errno); return ret; } break; case ZBD_DM_NONE: break; } zone_idx_b = zbd_zone_idx(f, offset); zb = &f->zbd_info->zone_info[zone_idx_b]; zone_idx_e = zbd_zone_idx(f, offset + length); ze = &f->zbd_info->zone_info[zone_idx_e]; for (z = zb; z < ze; z++) { pthread_mutex_lock(&z->mutex); pthread_mutex_lock(&f->zbd_info->mutex); f->zbd_info->sectors_with_data -= z->wp - z->start; pthread_mutex_unlock(&f->zbd_info->mutex); z->wp = z->start; z->verify_block = 0; pthread_mutex_unlock(&z->mutex); } td->ts.nr_zone_resets += ze - zb; return ret; } /** * zbd_reset_zone - reset the write pointer of a single zone * @td: FIO thread data. * @f: FIO file associated with the disk for which to reset a write pointer. * @z: Zone to reset. * * Returns 0 upon success and a negative error code upon failure. */ static int zbd_reset_zone(struct thread_data *td, const struct fio_file *f, struct fio_zone_info *z) { int ret; dprint(FD_ZBD, "%s: resetting wp of zone %lu.\n", f->file_name, z - f->zbd_info->zone_info); ret = zbd_reset_range(td, f, z->start, (z+1)->start - z->start); return ret; } /* * Reset a range of zones. Returns 0 upon success and 1 upon failure. * @td: fio thread data. * @f: fio file for which to reset zones * @zb: first zone to reset. * @ze: first zone not to reset. * @all_zones: whether to reset all zones or only those zones for which the * write pointer is not a multiple of td->o.min_bs[DDIR_WRITE]. */ static int zbd_reset_zones(struct thread_data *td, struct fio_file *f, struct fio_zone_info *const zb, struct fio_zone_info *const ze, bool all_zones) { struct fio_zone_info *z, *start_z = ze; const uint32_t min_bs = td->o.min_bs[DDIR_WRITE]; bool reset_wp; int res = 0; dprint(FD_ZBD, "%s: examining zones %lu .. %lu\n", f->file_name, zb - f->zbd_info->zone_info, ze - f->zbd_info->zone_info); assert(f->fd != -1); for (z = zb; z < ze; z++) { pthread_mutex_lock(&z->mutex); switch (z->type) { case BLK_ZONE_TYPE_SEQWRITE_REQ: reset_wp = all_zones ? z->wp != z->start : (td->o.td_ddir & TD_DDIR_WRITE) && z->wp % min_bs != 0; if (start_z == ze && reset_wp) { start_z = z; } else if (start_z < ze && !reset_wp) { dprint(FD_ZBD, "%s: resetting zones %lu .. %lu\n", f->file_name, start_z - f->zbd_info->zone_info, z - f->zbd_info->zone_info); if (zbd_reset_range(td, f, start_z->start, z->start - start_z->start) < 0) res = 1; start_z = ze; } break; default: if (start_z == ze) break; dprint(FD_ZBD, "%s: resetting zones %lu .. %lu\n", f->file_name, start_z - f->zbd_info->zone_info, z - f->zbd_info->zone_info); if (zbd_reset_range(td, f, start_z->start, z->start - start_z->start) < 0) res = 1; start_z = ze; break; } } if (start_z < ze) { dprint(FD_ZBD, "%s: resetting zones %lu .. %lu\n", f->file_name, start_z - f->zbd_info->zone_info, z - f->zbd_info->zone_info); if (zbd_reset_range(td, f, start_z->start, z->start - start_z->start) < 0) res = 1; } for (z = zb; z < ze; z++) pthread_mutex_unlock(&z->mutex); return res; } /* * Reset zbd_info.write_cnt, the counter that counts down towards the next * zone reset. */ static void zbd_reset_write_cnt(const struct thread_data *td, const struct fio_file *f) { assert(0 <= td->o.zrf.u.f && td->o.zrf.u.f <= 1); pthread_mutex_lock(&f->zbd_info->mutex); f->zbd_info->write_cnt = td->o.zrf.u.f ? min(1.0 / td->o.zrf.u.f, 0.0 + UINT_MAX) : UINT_MAX; pthread_mutex_unlock(&f->zbd_info->mutex); } static bool zbd_dec_and_reset_write_cnt(const struct thread_data *td, const struct fio_file *f) { uint32_t write_cnt = 0; pthread_mutex_lock(&f->zbd_info->mutex); assert(f->zbd_info->write_cnt); if (f->zbd_info->write_cnt) write_cnt = --f->zbd_info->write_cnt; if (write_cnt == 0) zbd_reset_write_cnt(td, f); pthread_mutex_unlock(&f->zbd_info->mutex); return write_cnt == 0; } /* Check whether the value of zbd_info.sectors_with_data is correct. */ static void check_swd(const struct thread_data *td, const struct fio_file *f) { #if 0 struct fio_zone_info *zb, *ze, *z; uint64_t swd; zb = &f->zbd_info->zone_info[zbd_zone_idx(f, f->file_offset)]; ze = &f->zbd_info->zone_info[zbd_zone_idx(f, f->file_offset + f->io_size)]; swd = 0; for (z = zb; z < ze; z++) { pthread_mutex_lock(&z->mutex); swd += z->wp - z->start; } pthread_mutex_lock(&f->zbd_info->mutex); assert(f->zbd_info->sectors_with_data == swd); pthread_mutex_unlock(&f->zbd_info->mutex); for (z = zb; z < ze; z++) pthread_mutex_unlock(&z->mutex); #endif } void zbd_file_reset(struct thread_data *td, struct fio_file *f) { struct fio_zone_info *zb, *ze, *z; uint32_t zone_idx_e; uint64_t swd = 0; if (!f->zbd_info) return; zb = &f->zbd_info->zone_info[zbd_zone_idx(f, f->file_offset)]; zone_idx_e = zbd_zone_idx(f, f->file_offset + f->io_size); ze = &f->zbd_info->zone_info[zone_idx_e]; for (z = zb ; z < ze; z++) { pthread_mutex_lock(&z->mutex); swd += z->wp - z->start; } pthread_mutex_lock(&f->zbd_info->mutex); f->zbd_info->sectors_with_data = swd; pthread_mutex_unlock(&f->zbd_info->mutex); for (z = zb ; z < ze; z++) pthread_mutex_unlock(&z->mutex); dprint(FD_ZBD, "%s(%s): swd = %ld\n", __func__, f->file_name, swd); /* * If data verification is enabled reset the affected zones before * writing any data to avoid that a zone reset has to be issued while * writing data, which causes data loss. */ zbd_reset_zones(td, f, zb, ze, td->o.verify != VERIFY_NONE && (td->o.td_ddir & TD_DDIR_WRITE) && td->runstate != TD_VERIFYING); zbd_reset_write_cnt(td, f); } /* The caller must hold f->zbd_info->mutex. */ static bool is_zone_open(const struct thread_data *td, const struct fio_file *f, unsigned int zone_idx) { struct zoned_block_device_info *zbdi = f->zbd_info; int i; assert(td->o.max_open_zones <= ARRAY_SIZE(zbdi->open_zones)); assert(zbdi->num_open_zones <= td->o.max_open_zones); for (i = 0; i < zbdi->num_open_zones; i++) if (zbdi->open_zones[i] == zone_idx) return true; return false; } /* * Open a ZBD zone if it was not yet open. Returns true if either the zone was * already open or if opening a new zone is allowed. Returns false if the zone * was not yet open and opening a new zone would cause the zone limit to be * exceeded. */ static bool zbd_open_zone(struct thread_data *td, const struct io_u *io_u, uint32_t zone_idx) { const uint32_t min_bs = td->o.min_bs[DDIR_WRITE]; const struct fio_file *f = io_u->file; struct fio_zone_info *z = &f->zbd_info->zone_info[zone_idx]; bool res = true; if (z->cond == BLK_ZONE_COND_OFFLINE) return false; /* * Skip full zones with data verification enabled because resetting a * zone causes data loss and hence causes verification to fail. */ if (td->o.verify != VERIFY_NONE && zbd_zone_full(f, z, min_bs)) return false; /* Zero means no limit */ if (!td->o.max_open_zones) return true; pthread_mutex_lock(&f->zbd_info->mutex); if (is_zone_open(td, f, zone_idx)) goto out; res = false; if (f->zbd_info->num_open_zones >= td->o.max_open_zones) goto out; dprint(FD_ZBD, "%s: opening zone %d\n", f->file_name, zone_idx); f->zbd_info->open_zones[f->zbd_info->num_open_zones++] = zone_idx; z->open = 1; res = true; out: pthread_mutex_unlock(&f->zbd_info->mutex); return res; } /* The caller must hold f->zbd_info->mutex */ static void zbd_close_zone(struct thread_data *td, const struct fio_file *f, unsigned int open_zone_idx) { uint32_t zone_idx; assert(open_zone_idx < f->zbd_info->num_open_zones); zone_idx = f->zbd_info->open_zones[open_zone_idx]; memmove(f->zbd_info->open_zones + open_zone_idx, f->zbd_info->open_zones + open_zone_idx + 1, (FIO_MAX_OPEN_ZBD_ZONES - (open_zone_idx + 1)) * sizeof(f->zbd_info->open_zones[0])); f->zbd_info->num_open_zones--; f->zbd_info->zone_info[zone_idx].open = 0; } /* * Modify the offset of an I/O unit that does not refer to an open zone such * that it refers to an open zone. Close an open zone and open a new zone if * necessary. This algorithm can only work correctly if all write pointers are * a multiple of the fio block size. The caller must neither hold z->mutex * nor f->zbd_info->mutex. Returns with z->mutex held upon success. */ struct fio_zone_info *zbd_convert_to_open_zone(struct thread_data *td, struct io_u *io_u) { const uint32_t min_bs = td->o.min_bs[io_u->ddir]; const struct fio_file *f = io_u->file; struct fio_zone_info *z; unsigned int open_zone_idx = -1; uint32_t zone_idx, new_zone_idx; int i; assert(is_valid_offset(f, io_u->offset)); if (td->o.max_open_zones) { /* * This statement accesses f->zbd_info->open_zones[] on purpose * without locking. */ zone_idx = f->zbd_info->open_zones[(io_u->offset - f->file_offset) * f->zbd_info->num_open_zones / f->io_size]; } else { zone_idx = zbd_zone_idx(f, io_u->offset); } dprint(FD_ZBD, "%s(%s): starting from zone %d (offset %lld, buflen %lld)\n", __func__, f->file_name, zone_idx, io_u->offset, io_u->buflen); /* * Since z->mutex is the outer lock and f->zbd_info->mutex the inner * lock it can happen that the state of the zone with index zone_idx * has changed after 'z' has been assigned and before f->zbd_info->mutex * has been obtained. Hence the loop. */ for (;;) { z = &f->zbd_info->zone_info[zone_idx]; pthread_mutex_lock(&z->mutex); pthread_mutex_lock(&f->zbd_info->mutex); if (td->o.max_open_zones == 0) goto examine_zone; if (f->zbd_info->num_open_zones == 0) { pthread_mutex_unlock(&f->zbd_info->mutex); pthread_mutex_unlock(&z->mutex); dprint(FD_ZBD, "%s(%s): no zones are open\n", __func__, f->file_name); return NULL; } open_zone_idx = (io_u->offset - f->file_offset) * f->zbd_info->num_open_zones / f->io_size; assert(open_zone_idx < f->zbd_info->num_open_zones); new_zone_idx = f->zbd_info->open_zones[open_zone_idx]; if (new_zone_idx == zone_idx) break; zone_idx = new_zone_idx; pthread_mutex_unlock(&f->zbd_info->mutex); pthread_mutex_unlock(&z->mutex); } /* Both z->mutex and f->zbd_info->mutex are held. */ examine_zone: if (z->wp + min_bs <= (z+1)->start) { pthread_mutex_unlock(&f->zbd_info->mutex); goto out; } dprint(FD_ZBD, "%s(%s): closing zone %d\n", __func__, f->file_name, zone_idx); if (td->o.max_open_zones) zbd_close_zone(td, f, open_zone_idx); pthread_mutex_unlock(&f->zbd_info->mutex); /* Only z->mutex is held. */ /* Zone 'z' is full, so try to open a new zone. */ for (i = f->io_size / f->zbd_info->zone_size; i > 0; i--) { zone_idx++; pthread_mutex_unlock(&z->mutex); z++; if (!is_valid_offset(f, z->start)) { /* Wrap-around. */ zone_idx = zbd_zone_idx(f, f->file_offset); z = &f->zbd_info->zone_info[zone_idx]; } assert(is_valid_offset(f, z->start)); pthread_mutex_lock(&z->mutex); if (z->open) continue; if (zbd_open_zone(td, io_u, zone_idx)) goto out; } /* Only z->mutex is held. */ /* Check whether the write fits in any of the already opened zones. */ pthread_mutex_lock(&f->zbd_info->mutex); for (i = 0; i < f->zbd_info->num_open_zones; i++) { zone_idx = f->zbd_info->open_zones[i]; pthread_mutex_unlock(&f->zbd_info->mutex); pthread_mutex_unlock(&z->mutex); z = &f->zbd_info->zone_info[zone_idx]; pthread_mutex_lock(&z->mutex); if (z->wp + min_bs <= (z+1)->start) goto out; pthread_mutex_lock(&f->zbd_info->mutex); } pthread_mutex_unlock(&f->zbd_info->mutex); pthread_mutex_unlock(&z->mutex); dprint(FD_ZBD, "%s(%s): did not open another zone\n", __func__, f->file_name); return NULL; out: dprint(FD_ZBD, "%s(%s): returning zone %d\n", __func__, f->file_name, zone_idx); io_u->offset = z->start; return z; } /* The caller must hold z->mutex. */ static struct fio_zone_info *zbd_replay_write_order(struct thread_data *td, struct io_u *io_u, struct fio_zone_info *z) { const struct fio_file *f = io_u->file; const uint32_t min_bs = td->o.min_bs[DDIR_WRITE]; if (!zbd_open_zone(td, io_u, z - f->zbd_info->zone_info)) { pthread_mutex_unlock(&z->mutex); z = zbd_convert_to_open_zone(td, io_u); assert(z); } if (z->verify_block * min_bs >= f->zbd_info->zone_size) log_err("%s: %d * %d >= %ld\n", f->file_name, z->verify_block, min_bs, f->zbd_info->zone_size); io_u->offset = z->start + z->verify_block++ * min_bs; return z; } /* * Find another zone for which @io_u fits below the write pointer. Start * searching in zones @zb + 1 .. @zl and continue searching in zones * @zf .. @zb - 1. * * Either returns NULL or returns a zone pointer and holds the mutex for that * zone. */ static struct fio_zone_info * zbd_find_zone(struct thread_data *td, struct io_u *io_u, struct fio_zone_info *zb, struct fio_zone_info *zl) { const uint32_t min_bs = td->o.min_bs[io_u->ddir]; const struct fio_file *f = io_u->file; struct fio_zone_info *z1, *z2; const struct fio_zone_info *const zf = &f->zbd_info->zone_info[zbd_zone_idx(f, f->file_offset)]; /* * Skip to the next non-empty zone in case of sequential I/O and to * the nearest non-empty zone in case of random I/O. */ for (z1 = zb + 1, z2 = zb - 1; z1 < zl || z2 >= zf; z1++, z2--) { if (z1 < zl && z1->cond != BLK_ZONE_COND_OFFLINE) { pthread_mutex_lock(&z1->mutex); if (z1->start + min_bs <= z1->wp) return z1; pthread_mutex_unlock(&z1->mutex); } else if (!td_random(td)) { break; } if (td_random(td) && z2 >= zf && z2->cond != BLK_ZONE_COND_OFFLINE) { pthread_mutex_lock(&z2->mutex); if (z2->start + min_bs <= z2->wp) return z2; pthread_mutex_unlock(&z2->mutex); } } dprint(FD_ZBD, "%s: adjusting random read offset failed\n", f->file_name); return NULL; } /** * zbd_post_submit - update the write pointer and unlock the zone lock * @io_u: I/O unit * @success: Whether or not the I/O unit has been executed successfully * * For write and trim operations, update the write pointer of all affected * zones. */ static void zbd_post_submit(const struct io_u *io_u, bool success) { struct zoned_block_device_info *zbd_info; struct fio_zone_info *z; uint32_t zone_idx; uint64_t end, zone_end; zbd_info = io_u->file->zbd_info; if (!zbd_info) return; zone_idx = zbd_zone_idx(io_u->file, io_u->offset); end = io_u->offset + io_u->buflen; z = &zbd_info->zone_info[zone_idx]; assert(zone_idx < zbd_info->nr_zones); if (z->type != BLK_ZONE_TYPE_SEQWRITE_REQ) return; if (!success) goto unlock; switch (io_u->ddir) { case DDIR_WRITE: zone_end = min(end, (z + 1)->start); pthread_mutex_lock(&zbd_info->mutex); /* * z->wp > zone_end means that one or more I/O errors * have occurred. */ if (z->wp <= zone_end) zbd_info->sectors_with_data += zone_end - z->wp; pthread_mutex_unlock(&zbd_info->mutex); z->wp = zone_end; break; case DDIR_TRIM: assert(z->wp == z->start); break; default: break; } unlock: pthread_mutex_unlock(&z->mutex); } bool zbd_unaligned_write(int error_code) { switch (error_code) { case EIO: case EREMOTEIO: return true; } return false; } /** * zbd_adjust_block - adjust the offset and length as necessary for ZBD drives * @td: FIO thread data. * @io_u: FIO I/O unit. * * Locking strategy: returns with z->mutex locked if and only if z refers * to a sequential zone and if io_u_accept is returned. z is the zone that * corresponds to io_u->offset at the end of this function. */ enum io_u_action zbd_adjust_block(struct thread_data *td, struct io_u *io_u) { const struct fio_file *f = io_u->file; uint32_t zone_idx_b; struct fio_zone_info *zb, *zl, *orig_zb; uint32_t orig_len = io_u->buflen; uint32_t min_bs = td->o.min_bs[io_u->ddir]; uint64_t new_len; int64_t range; if (!f->zbd_info) return io_u_accept; assert(is_valid_offset(f, io_u->offset)); assert(io_u->buflen); zone_idx_b = zbd_zone_idx(f, io_u->offset); zb = &f->zbd_info->zone_info[zone_idx_b]; orig_zb = zb; /* Accept the I/O offset for conventional zones. */ if (zb->type == BLK_ZONE_TYPE_CONVENTIONAL) return io_u_accept; /* * Accept the I/O offset for reads if reading beyond the write pointer * is enabled. */ if (zb->cond != BLK_ZONE_COND_OFFLINE && io_u->ddir == DDIR_READ && td->o.read_beyond_wp) return io_u_accept; pthread_mutex_lock(&zb->mutex); switch (io_u->ddir) { case DDIR_READ: if (td->runstate == TD_VERIFYING) { zb = zbd_replay_write_order(td, io_u, zb); goto accept; } /* * Check that there is enough written data in the zone to do an * I/O of at least min_bs B. If there isn't, find a new zone for * the I/O. */ range = zb->cond != BLK_ZONE_COND_OFFLINE ? zb->wp - zb->start : 0; if (range < min_bs || ((!td_random(td)) && (io_u->offset + min_bs > zb->wp))) { pthread_mutex_unlock(&zb->mutex); zl = &f->zbd_info->zone_info[zbd_zone_idx(f, f->file_offset + f->io_size)]; zb = zbd_find_zone(td, io_u, zb, zl); if (!zb) { dprint(FD_ZBD, "%s: zbd_find_zone(%lld, %llu) failed\n", f->file_name, io_u->offset, io_u->buflen); goto eof; } /* * zbd_find_zone() returned a zone with a range of at * least min_bs. */ range = zb->wp - zb->start; assert(range >= min_bs); if (!td_random(td)) io_u->offset = zb->start; } /* * Make sure the I/O is within the zone valid data range while * maximizing the I/O size and preserving randomness. */ if (range <= io_u->buflen) io_u->offset = zb->start; else if (td_random(td)) io_u->offset = zb->start + ((io_u->offset - orig_zb->start) % (range - io_u->buflen)) / min_bs * min_bs; /* * Make sure the I/O does not cross over the zone wp position. */ new_len = min((unsigned long long)io_u->buflen, (unsigned long long)(zb->wp - io_u->offset)); new_len = new_len / min_bs * min_bs; if (new_len < io_u->buflen) { io_u->buflen = new_len; dprint(FD_IO, "Changed length from %u into %llu\n", orig_len, io_u->buflen); } assert(zb->start <= io_u->offset); assert(io_u->offset + io_u->buflen <= zb->wp); goto accept; case DDIR_WRITE: if (io_u->buflen > f->zbd_info->zone_size) goto eof; if (!zbd_open_zone(td, io_u, zone_idx_b)) { pthread_mutex_unlock(&zb->mutex); zb = zbd_convert_to_open_zone(td, io_u); if (!zb) goto eof; zone_idx_b = zb - f->zbd_info->zone_info; } /* Check whether the zone reset threshold has been exceeded */ if (td->o.zrf.u.f) { check_swd(td, f); if (f->zbd_info->sectors_with_data >= f->io_size * td->o.zrt.u.f && zbd_dec_and_reset_write_cnt(td, f)) { zb->reset_zone = 1; } } /* Reset the zone pointer if necessary */ if (zb->reset_zone || zbd_zone_full(f, zb, min_bs)) { assert(td->o.verify == VERIFY_NONE); /* * Since previous write requests may have been submitted * asynchronously and since we will submit the zone * reset synchronously, wait until previously submitted * write requests have completed before issuing a * zone reset. */ io_u_quiesce(td); zb->reset_zone = 0; if (zbd_reset_zone(td, f, zb) < 0) goto eof; check_swd(td, f); } /* Make writes occur at the write pointer */ assert(!zbd_zone_full(f, zb, min_bs)); io_u->offset = zb->wp; if (!is_valid_offset(f, io_u->offset)) { dprint(FD_ZBD, "Dropped request with offset %llu\n", io_u->offset); goto eof; } /* * Make sure that the buflen is a multiple of the minimal * block size. Give up if shrinking would make the request too * small. */ new_len = min((unsigned long long)io_u->buflen, (zb + 1)->start - io_u->offset); new_len = new_len / min_bs * min_bs; if (new_len == io_u->buflen) goto accept; if (new_len >= min_bs) { io_u->buflen = new_len; dprint(FD_IO, "Changed length from %u into %llu\n", orig_len, io_u->buflen); goto accept; } log_err("Zone remainder %lld smaller than minimum block size %d\n", ((zb + 1)->start - io_u->offset), min_bs); goto eof; case DDIR_TRIM: /* fall-through */ case DDIR_SYNC: case DDIR_DATASYNC: case DDIR_SYNC_FILE_RANGE: case DDIR_WAIT: case DDIR_LAST: case DDIR_INVAL: goto accept; } assert(false); accept: assert(zb); assert(zb->cond != BLK_ZONE_COND_OFFLINE); assert(!io_u->post_submit); io_u->post_submit = zbd_post_submit; return io_u_accept; eof: if (zb) pthread_mutex_unlock(&zb->mutex); return io_u_eof; } /* Return a string with ZBD statistics */ char *zbd_write_status(const struct thread_stat *ts) { char *res; if (asprintf(&res, "; %ld zone resets", ts->nr_zone_resets) < 0) return NULL; return res; }