384 lines
15 KiB
Markdown
384 lines
15 KiB
Markdown
Turbo NSS
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---------
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Turbonss is a plugin for GNU Name Service Switch (NSS) functionality of GNU C
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Library (glibc). Turbonss implements lookup for `user` and `passwd` database
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entries (i.e. system users, groups, and group memberships). It's main goal is
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performance, with focus on making [`id(1)`][id] run as fast as possible.
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Turbonss is optimized for reading. If the data changes in any way, the whole
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file will need to be regenerated (and tooling only supports only full
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generation). It was created, and best suited, for environments that have a
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central user & group database which then needs to be distributed to many
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servers/services, and the data does not change very often (e.g. hourly).
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To understand more about name service switch, start with
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[`nsswitch.conf(5)`][nsswitch].
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Design & constraints
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--------------------
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To be fast, the user/group database (later: DB) has to be small
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([background][data-oriented-design]). It encodes user & group information in a
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way that minimizes the DB size, and reduces jumping across the DB ("chasing
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pointers and thrashing CPU cache").
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To understand how this is done efficiently, let's analyze the
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[`getpwnam_r(3)`][getpwnam_r] in high level. This API call accepts a username
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and returns the following user information:
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```
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struct passwd {
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char *pw_name; /* username */
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char *pw_passwd; /* user password */
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uid_t pw_uid; /* user ID */
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gid_t pw_gid; /* group ID */
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char *pw_gecos; /* user information */
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char *pw_dir; /* home directory */
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char *pw_shell; /* shell program */
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};
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```
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Turbonss, among others, implements this call, and takes the following steps to
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resolve a username to a `struct passwd*`:
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- Open the DB (using `mmap`) and interpret it's first 64 bytes as a `*struct
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Header`. The header stores offsets to the sections of the file. This needs to
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be done once, when the NSS library is loaded.
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- Hash the username using a perfect hash function. Perfect hash function
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returns a number `n ∈ [0,N-1]`, where N is the total number of users.
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- Jump to the `n`'th location in the `idx_name2user` section, which contains
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the index `i` to the user's information.
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- Jump to the location `i` of section `Users`, which stores the full user
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information.
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- Decode the user information (which is all in a continuous memory block) and
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return it to the caller.
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In total, that's one hash for the username (~150ns), two pointer jumps within
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the group file (to sections `idx_name2user` and `Users`), and, now that the
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user record is found, `memcpy` for each field.
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The turbonss DB file is be `mmap`-ed, making it simple to jump across the file
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using pointer arithmetic. This also reduces memory usage, as the mmap'ed
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regions are shared. Turbonss reads do not consume any heap space.
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Tight packing places some constraints on the underlying data:
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- Permitted length of username and groupname: 1-32 bytes.
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- Permitted length of shell and home: 1-256 bytes.
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- Permitted comment ("gecos") length: 0-255 bytes.
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- User name, groupname, gecos and shell must be utf8-encoded.
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- User and Groups sections are up to 2^35B (~34GB) large. Assuming an "average"
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user record takes 50 bytes, this section would fit ~660M users. The
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worst-case upper bound is left as an exercise to the reader.
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Sorting is stable. In v0:
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- Groups are sorted by gid, ascending.
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- Users are sorted by their name, ascending by the unicode codepoints
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(locale-independent).
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Checking out and building
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-------------------------
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```
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$ git clone --recursive https://git.sr.ht/~motiejus/turbonss
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```
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Alternatively, if you forgot `--recursive`:
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```
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$ git submodule update --init
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```
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And run tests:
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```
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$ zig build test
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```
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Other commands will be documented as they are implemented.
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This project uses [git subtrac][git-subtrac] for managing dependencies. They
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work just like regular submodules, except all the refs of the submodules are in
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this repository. Repeat after me: all the submodules are in this repository.
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So if you have a copy of this repo, dependencies will not disappear.
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remarks on `id(1)`
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------------------
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A known implementation runs id(1) at ~250 rps sequentially on ~20k users and
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~10k groups. Our rps target is much higher.
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To better reason about the trade-offs, it is useful to understand how `id(1)`
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is implemented, in rough terms:
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- lookup user by name ([`getpwent_r(3)`][getpwent]).
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- get all gids for the user ([`getgrouplist(3)`][getgrouplist]). Note: it is
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actually using `initgroups_dyn`, accepts a uid, and is very poorly
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documented.
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- for each additional gid, get the `struct group*`
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([`getgrgid_r(3)`][getgrgid_r]).
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Assuming a member is in ~100 groups on average, to reach 10k id/s translates to
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1M group lookups per second. We need to convert gid to a group index, and group
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index to a group gid/name quickly.
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Caveat: `struct group` contains an array of pointers to names of group members
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(`char **gr_mem`). However, `id` does not use that information, resulting in
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read amplification, sometimes by 10-100x. Therefore, if `argv[0] == "id"`, our
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implementation of [`getgrid_r(3)`][getgrid] returns the `struct group*` without
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the members. This speeds up `id` by about 10x on a known NSS implementation.
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Relatedly, because [`getgrid_r(3)`][getgrid] does not need the group members,
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the group members are stored in a different DB section, reducing the `Groups`
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section and making more of it fit the CPU caches.
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Turbonss header
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---------------
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The turbonss header looks like this:
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```
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OFFSET TYPE NAME DESCRIPTION
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0 [4]u8 magic f0 9f a4 b7
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4 u8 version 0
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5 u8 endian 0 for little, 1 for big
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6 u8 nblocks_shell_blob max value: 63
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7 u8 num_shells max value: 63
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8 u32 num_groups number of group entries
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12 u32 num_users number of passwd entries
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16 u32 nblocks_bdz_gid bdz_gid section block count
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20 u32 nblocks_bdz_groupname
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24 u32 nblocks_bdz_uid
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28 u32 nblocks_bdz_username
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32 u64 nblocks_groups
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40 u64 nblocks_users
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48 u64 nblocks_groupmembers
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56 u64 nblocks_additional_gids
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64 u64 getgr_bufsize
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72 u64 getpw_bufsize
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80 [48]u8 padding
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```
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`magic` is 0xf09fa4b7, and `version` must be `0`. All integers are
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native-endian. `nblocks_*` is the count of blocks of a particular section; this
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helps calculate the offsets to all sections.
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Some numbers, like `nblocks_shell_blob`, `num_shells`, would fit to smaller
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number of bytes. However, interpreting `[2]u6` with `xxd(1)` is harder than
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interpreting `[2]u8`. Therefore we are using the space we have to make these
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integers byte-wide.
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`getgr_bufsize` and `getpw_bufsize` is a hint for the caller of `getgr*` and
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`getpw*`-family calls. This is the recommended size of the buffer, so the
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caller does not receive `ENOMEM`.
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Primitive types
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---------------
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`User` and `Group` entries are sorted by the order they were received in the input
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file. All entries are aligned to 8 bytes. All `User` and `Group` entries are
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referred by their byte offset in the `Users` and `Groups` section relative to
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the beginning of the section.
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```
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const PackedGroup = packed struct {
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gid: u32,
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padding: u3,
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groupname_len: u5,
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}
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```
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PackedGroup is followed by the group name (of length `groupname_len`), followed
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by a varint-compressed offset to the groupmembers section, followed by 8b padding.
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PackedUser is a bit more involved:
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```
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pub const PackedUser = packed struct {
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uid: u32,
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gid: u32,
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shell_len_or_idx: u8,
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shell_here: bool,
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name_is_a_suffix: bool,
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home_len: u6,
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name_len: u5,
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gecos_len: u11,
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}
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```
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... followed by `userdata: []u8`:
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- home.
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- name (optional).
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- gecos.
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- shell (optional).
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- `additional_gids_offset`: varint.
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First byte of home is stored right after the `gecos_len` field, and its length
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is `home_len`. The same logic applies to all the `stringdata` fields: there is
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a way to calculate their relative position from the length of the fields before
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them.
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PackedUser employs two "simple" compression techniques:
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- shells are often shared across different users, see the "Shells" section.
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- `name` is frequently a suffix of `home`. For example, `/home/vidmantas` and
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`vidmantas`. In this case storing both name and home is wasteful. Therefore
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name has two options:
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1. `name_is_a_suffix=true`: name is a suffix of the home dir. Then `name`
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starts at the `home_len - name_len`'th byte of `home`, and ends at the same
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place as `home`.
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2. `name_is_a_suffix=false`: name begins one byte after home, and it's length
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is `name_len`.
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The last field `additional_gids_offset: varint` points to the `additional_gids`
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section for this user.
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Shells
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------
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Normally there is a limited number of separate shells even in huge user
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databases. A few examples: `/bin/bash`, `/usr/bin/nologin`, `/bin/zsh` among
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others. Therefore, "shells" have an optimization: they can be pointed by in the
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external list, or, if they are unique to the user, reside among the user's
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data.
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255 most popular shells (i.e. referred to by at least two User entries) are
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stored externally in "Shells" area. The less popular ones are stored with
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userdata.
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Shells section consists of two sub-sections: the index and the blob. The index
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is an array of offsets: the i'th shell starts at `offsets[i]` byte, and ends at
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`offsets[i+1]` byte. If there is at least one shell in the shell section, the
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index contains a sentinel index as the last element, which signifies the position
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of the last byte of the shell blob.
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`shell_here=true` in the User struct means the shell is stored with userdata,
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and it's length is `shell_len_or_idx`. `shell_here=false` means it is stored in
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the `Shells` section, and it's index is `shell_len_or_idx` (and the actual
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string start and end offsets are resolved as described in the paragraph above).
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Variable-length integers (varints)
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----------------------------------
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Varint is an efficiently encoded integer (packed for small values). Same as
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[protocol buffer varints][varint], except the largest possible value is `u64`.
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They compress integers well. Varints are stored for group memberships.
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Group memberships
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-----------------
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There are two group memberships at play:
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1. Given a group (gid/name), resolve the members' names (e.g. `getgrgid`).
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2. Given a username, resolve user's group gids (for `initgroups(3)`).
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When group's memberships are resolved in (1), the same call also requires other
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group information: gid and group name. Therefore it makes sense to store a
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pointer to the group members in the group information itself. However, the
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memberships are not *always* necessary (see remarks about `id(1)`), therefore
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the memberships will be stored separately, outside of the groups section.
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Similarly, when user's groups are resolved in (2), they are not always necessary
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(i.e. not part of `struct user*`), therefore the memberships themselves are
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stored out of bound.
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`groupmembers` and `additional_gids` store group and user memberships
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respectively. Membership IDs are packed — not necessitating random access, thus
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suitable for compression.
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- `groupmembers` consists of a number X followed by a list of offsets to User
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records, because `getgr*` returns pointers to membernames, thus a name has to
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be immediately resolvable.
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- `additional_gids` is a list of gids, because `initgroups_dyn` (and friends)
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returns an array of gids.
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Each entry of `groupmembers` and `additional_gids` starts with a varint N,
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which is the number of upcoming elements. Then N delta-compressed varints,
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which are:
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- **additional_gids** a list of gids.
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- **groupmembers** byte-offsets to the User records in the `users` section.
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Indices
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-------
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Now that we've sketched the implementation of `id(3)`, it's clearer to
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understand which operations need to be fast; in order of importance:
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1. lookup gid -> group info (this is on hot path in id) without members.
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2. lookup username -> user's groups.
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3. lookup uid -> user.
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4. lookup groupname -> group.
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5. lookup username -> user.
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These indices can use perfect hashing like [bdz from cmph][cmph]: a perfect
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hash hashes a list of bytes to a sequential list of integers. Perfect hashing
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algorithms require some space, and take some time to calculate ("hashing
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duration"). I've tested BDZ, which hashes `[][]u8` to a sequential list of
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integers (not preserving order) and CHM, preserves order. BDZ accepts an
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optional argument `3 <= b <= 10`.
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* BDZ algorithm requires (b=3, 900KB, b=7, 338KB, b=10, 306KB) for 1M values.
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* Latency to resolve 1M keys: (170ms, 180ms, 230ms, respectively).
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* Packed vs non-packed latency differences are not meaningful.
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CHM retains order, however, 1M keys weigh 8MB. 10k keys are ~20x larger with
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CHM than with BDZ, eliminating the benefit of preserved ordering: we can just
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have a separate index.
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None of the tested perfect hashing algorithms makes the distinction between
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existing (in the initial dictionary) and new keys. In other words, HASH(value)
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will be pointing to a number `n ∈ [0,N-1]`, regardless whether the value was in
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the initial dictionary. Therefore one must always confirm, after calculating
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the hash, that the key matches what's been hashed.
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`idx_*` sections are of type `[]u32` and are pointing to the respective
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`Groups` and `Users` entries (from the beginning of the respective section).
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Since User and Group records are 8-byte aligned, the actual offset to the
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record is acquired by right-shifting this value by 3 bits.
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Database file structure
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-----------------------
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Each section is padded to 64 bytes.
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```
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SECTION SIZE DESCRIPTION
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header 128 see "Turbonss header" section
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bdz_gid ? bdz(gid)
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bdz_groupname ? bdz(groupname)
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bdz_uid ? bdz(uid)
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bdz_username ? bdz(username)
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idx_gid2group len(group)*4 bdz->offset Groups
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idx_groupname2group len(group)*4 bdz->offset Groups
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idx_uid2user len(user)*4 bdz->offset Users
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idx_name2user len(user)*4 bdz->offset Users
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shell_index len(shells)*2 shell index array
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shell_blob <= 65280 shell data blob (max 255*256 bytes)
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groups ? packed Group entries (8b padding)
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users ? packed User entries (8b padding)
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groupmembers ? per-group delta varint memberlist (no padding)
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additional_gids ? per-user delta varint gidlist (no padding)
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```
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Section creation order:
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1. ✅ `bdz_*`.
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1. ✅ `shell_index`, `shell_blob`.
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1. ✅ `additional_gids`.
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1. ✅ `users` requires `additional_gids` and shell.
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1. ✅ `groupmembers` requires `users`.
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1. ✅ `groups` requires `groupmembers`.
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1. ✅ `idx_*`. requires offsets to `groups` and `users`.
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1. ✅ Header.
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[git-subtrac]: https://apenwarr.ca/log/20191109
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[cmph]: http://cmph.sourceforge.net/
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[id]: https://linux.die.net/man/1/id
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[nsswitch]: https://linux.die.net/man/5/nsswitch.conf
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[data-oriented-design]: https://media.handmade-seattle.com/practical-data-oriented-design/
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[getpwnam_r]: https://linux.die.net/man/3/getpwnam_r
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[varint]: https://developers.google.com/protocol-buffers/docs/encoding#varints
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[getpwent]: https://www.man7.org/linux/man-pages/man3/getpwent_r.3.html
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[getgrouplist]: https://www.man7.org/linux/man-pages/man3/getgrouplist.3.html
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[getgrid]: https://www.man7.org/linux/man-pages/man3/getgrid_r.3.html
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