Advanced Format

すべてのストレージデバイスには、使うことのできる最小の記憶単位が存在します。この利用可能な最小単位は一般にセクタと呼ばれており、従来のストレージデバイスの回転部品を最小に分割したものでした (ソリッドステートドライブはメモリセルを使用し、最小単位はページです)。[1] を参照してください。

異なるストレージデバイスは、異なるセクタサイズを使用します。2011 年以降、最近のハードディスクドライブは通常 (512 バイトではなく) 4 KiB セクタを使用します。ソリッドステートドライブは、複数のフォーマットをサポートしていることがあります。

異なる「レイヤー」(つまり、デバイス / スタックされたブロックデバイス / ファイルシステム) 間で同じセクタサイズを使用するべきです。同じセクタサイズを使わない場合、ファームウェアがファイルシステムのセクタと物理ドライブのセクタとの間でマッピングを行わなければなりません。これは通常、変換レイヤーによって透過的に行われますが、これは回避可能なオーバーヘッドであり、そうすることでパフォーマンスが向上します。

ハードディスクドライブ – Advanced Format

The Advanced Format is a generic term pertaining to any disk sector format used to store data on magnetic disks in hard disk drives that uses 4 kibibyte sectors instead of the traditional 512 byte sectors. The main idea behind using 4096-byte sectors is to increase the bit density on each track by reducing the number of gaps which hold Sync/DAM and error correction code (ECC) information between data sectors. The old format gave a format efficiency of 88.7%, whereas Advanced Format results in a format efficiency of 97.3%.

There are two types of Advanced Format drives:

• Advanced Format drives, marked with an orange "AF" logo: internally, they use 4k sectors, but provide an emulation layer for compatibility with operating systems which lack support for them.
• Advanced Format 4k native drives, marked with a blue "4Kn" logo: they require support from the operating system (Windows 8+, or Linux 2.6.31+). Because they do not need a translation layer, they are cheaper, however they might be incompatible with old tools.

Check supported sector sizes

The physical and logical sector size of hard disk /dev/sdX can be determined by reading the following sysfs entries:

$ cat /sys/class/block/sdX/queue/physical_block_size
$ cat /sys/class/block/sdX/queue/logical_block_size

Drives with a translation layer (see above) will usually report a logical block size of 512 (for backwards compatibility) and a physical block size of 4096 (indicating they are Advanced Format drives).

Tools which will report the sector of a drive (provided the drive will report it correctly) includes:

• fdisk:

  # LC_ALL=C fdisk -l /dev/sdX | grep 'Sector size'

• smartmontools:

  # smartctl -a /dev/sdX | grep 'Sector Size'

• hdparm:

  # hdparm -I /dev/sdX | grep 'Sector size:'

Note that both works even for USB-attached discs (if the USB bridge supports SAT aka SCSI/ATA Translation, ANSI INCITS 431-2007).

ソリッドステートドライブ

Most solid state drives (SSDs) report their sector size as 512 bytes, even though they use larger sectors - typically 4 KiB, 8 KiB, or sometimes larger. As a result, file systems cannot automatically optimize for the native sector size. To avoid sub-optimal performance, one can either:

• Manually specify the sector size when creating a file system,
• Change the native sector size reported by the device.

NVMe ドライブのサポートされているセクタサイズを調べる

Use smartmontools to check supported sector sizes:

# smartctl -a device

...
Supported LBA Sizes (NSID 0x1)
Id Fmt  Data  Metadt  Rel_Perf
 0 +     512       0         2
 1 -    4096       0         1
...

ネイティブのセクタサイズを設定する

As an alternative to manually overriding the auto-detected sector size, some SSDs can have their sector size changed during formatting, so that they report a number closer to their true sector size.

NVMe

To see whether a given NVMe device supports this, use the Identify Namespace command.

# nvme id-ns /dev/nvme0n1

nlbaf   : 0
[...]
lbaf  0 : ms:0   lbads:9  rp:0 (in use)

nlbaf is the number of LBA formats minus 1, so here there is only one format supported. The list of formats is at the end of the output. Here lbaf 0 means LBA format #0. It has an lbads (LBA data size) of 9, which means sectors are 2⁹ or 512 bytes. If the device is capable of 4 KiB sectors, there will be another entry here with an lbads of 12. The rp (Relative Performance) value indicates which format will provide the best performance, with 0 being the best. ms is (probably) the number of extra metadata bytes per sector, and this is not well supported under Linux so best to select a format with a value of 0 here.

To change the sector size, use nvme format and specify the preferred value with the --lbaf parameter. If nvme format fails, try putting the machine to sleep (e.g., with systemctl suspend) and then try running nvme format again after waking it. If nvme format still fails, fiddling with your BIOS settings might help.

SATA

For SATA devices, manufacturer specific programs must be used. Not all SATA devices support having the sector size changed.

Intel

For Intel use the Intel Memory and Storage (MAS) Tool (intel-mas-cli-tool^AUR) with the -set PhysicalSectorSize=4096 option.

Seagate

For Seagate use seagate-seachest^AUR.

Scan all drives to find the correct one, and print info from the one you found:

# SeaChest_Basics --scan
# SeaChest_Basics -d /dev/sgX -i

Should print out information about the drive. Make sure to check the serial number.

Check the logical block sizes supported by the drive:

# SeaChest_Format -d /dev/sgX --showSupportedFormats

If 4096 is listed, you can change the logical sector size to it as follows:

# SeaChest_Format -d /dev/sgX --setSectorSize=4096 --confirm this-will-erase-data

This will take a couple of minutes, after which your drive now uses a 4K native sector size.

パーティションのアライメント

パーティションを正しくアライメントすることで、読み込み・変更・書き込みの過剰なサイクルを回避できます。家庭用のコンピュータでは、各パーティションの開始位置とサイズを 1 MiB (1 048 576 バイト) 境界にアライメントするのが一般的です。これは、一般的に使用されているすべてのサイズ (1 MiB、512 KiB、128 KiB、4 KiB、512 B) で割り切ることができるので、一般的なページサイズとブロックサイズのシナリオすべてをカバーします。

• fdisk、cfdisk、sfdisk はアライメントを自動的に管理します。
• gdisk と cgdisk はアライメントを自動的に管理します。
  • sgdisk はデフォルトで、パーティションの開始位置のみをアライメントします。パーティションのサイズや終了位置のアライメントも有効化するには、-I/--align-end オプションを使ってください。
• Parted はパーティションの開始位置のみをアライメントし、サイズと終了位置はアライメントしません。パーティションを作成するときは、パーティションの終了位置をメビバイトかより大きな IEC 2進接頭辞で指定するようにしてください。

dm-crypt

As of Cryptsetup 2.4.0, luksFormat automatically detects the optimal encryption sector size for LUKS2 format [3].

However, for this to work, the device needs to report the correct default sector size, see #Setting native sector size.

After using cryptsetup luksFormat, you can check the sector size used by the LUKS2 volume with

# cryptsetup luksDump device | grep sector

If the default sector size is incorrect, you can force create a LUKS2 container with a 4K sector size and otherwise default options with:

# cryptsetup luksFormat --sector-size=4096 device

The command will abort on an error if the requested size does not match your device:

# cryptsetup luksFormat --sector-size 4096 device
(...)
Verify passphrase: 
Device size is not aligned to requested sector size.

If you encrypted your device with the wrong sector size, the device can be re-encrypted by running:

# cryptsetup reencrypt --sector-size=4096 device

ファイルシステム

mkfs.btrfs(8), mkfs.jfs(8), mkfs.nilfs2(8), mkfs.reiserfs(8) and mkswap(8) default to a 4096 byte sector size.

mkfs.ext4(8) defaults to 1024 byte sectors for file systems smaller than 512 MiB and 4096 byte sectors for 512 MiB and larger.

mkfs.xfs(8) defaults to 512 byte sectors, but will use 4096 for 512e and 4Kn disks.

mkfs.f2fs(8), mkfs.fat(8), mkfs.ntfs(8) and mkfs.udf(8) use the backing device's logical sector size. I.e. they will use 512 byte sectors for 512e disks and 4096 byte sectors for 4Kn disks.

If the storage device does not report the correct sector size, you can explicitly format the partitions according to the physical sector size.

In particular shingled magnetic recording (SMR) drives that are firmware-managed are severely and negatively impacted if using a logical sector size of 512 bytes if their physical sector size is of 4096 bytes. Those drives have different performance writing zones and remapping reallocation occurs while being idle, but during heavy active writes (e.g., RAID resilvering, backups, writing many small files, rsync, etc.), a different file system sector size could drop write speed to single digit megabytes/second, as the higher performance write areas get depleted, and the sector translation layer gets overworked on the shingled areas.

Here are some examples to set the 4096-byte sector size explicitly:

• ext4:

  # mkfs.ext4 -b 4096 /dev/device

• XFS:

  # mkfs.xfs -s size=4096 /dev/device

• FAT:

  # mkfs.fat -S 4096 /dev/device

• NTFS-3G:

  # mkfs.ntfs -Q -s 4096 /dev/device

• UDF:

  # mkfs.udf -b 4096 /dev/device

参照

• Western Digital’s Advanced Format: The 4K Sector Transition Begins
• White paper entitled "Advanced Format Technology."
• HDD のアライメントに失敗すると、読み込み/書き込みのパフォーマンスが劣化します。具体的な例は [4] を見てください。