LCOV - code coverage report
Current view: top level - libs/utils/src - shard.rs (source / functions) Coverage Total Hit
Test: b9d67f908f91f00e353a27440ba89f642a869959.info Lines: 81.2 % 245 199
Test Date: 2024-11-19 21:44:13 Functions: 42.7 % 89 38

            Line data    Source code
       1              : //! See `pageserver_api::shard` for description on sharding.
       2              : 
       3              : use std::{ops::RangeInclusive, str::FromStr};
       4              : 
       5              : use hex::FromHex;
       6              : use serde::{Deserialize, Serialize};
       7              : 
       8              : use crate::id::TenantId;
       9              : 
      10            0 : #[derive(Ord, PartialOrd, Eq, PartialEq, Clone, Copy, Serialize, Deserialize, Debug, Hash)]
      11              : pub struct ShardNumber(pub u8);
      12              : 
      13            0 : #[derive(Ord, PartialOrd, Eq, PartialEq, Clone, Copy, Serialize, Deserialize, Debug, Hash)]
      14              : pub struct ShardCount(pub u8);
      15              : 
      16              : /// Combination of ShardNumber and ShardCount.
      17              : ///
      18              : /// For use within the context of a particular tenant, when we need to know which shard we're
      19              : /// dealing with, but do not need to know the full ShardIdentity (because we won't be doing
      20              : /// any page->shard mapping), and do not need to know the fully qualified TenantShardId.
      21              : #[derive(Eq, PartialEq, PartialOrd, Ord, Clone, Copy, Hash)]
      22              : pub struct ShardIndex {
      23              :     pub shard_number: ShardNumber,
      24              :     pub shard_count: ShardCount,
      25              : }
      26              : 
      27              : /// Formatting helper, for generating the `shard_id` label in traces.
      28              : pub struct ShardSlug<'a>(&'a TenantShardId);
      29              : 
      30              : /// TenantShardId globally identifies a particular shard in a particular tenant.
      31              : ///
      32              : /// These are written as `<TenantId>-<ShardSlug>`, for example:
      33              : ///   # The second shard in a two-shard tenant
      34              : ///   072f1291a5310026820b2fe4b2968934-0102
      35              : ///
      36              : /// If the `ShardCount` is _unsharded_, the `TenantShardId` is written without
      37              : /// a shard suffix and is equivalent to the encoding of a `TenantId`: this enables
      38              : /// an unsharded [`TenantShardId`] to be used interchangably with a [`TenantId`].
      39              : ///
      40              : /// The human-readable encoding of an unsharded TenantShardId, such as used in API URLs,
      41              : /// is both forward and backward compatible with TenantId: a legacy TenantId can be
      42              : /// decoded as a TenantShardId, and when re-encoded it will be parseable
      43              : /// as a TenantId.
      44              : #[derive(Eq, PartialEq, PartialOrd, Ord, Clone, Copy, Hash)]
      45              : pub struct TenantShardId {
      46              :     pub tenant_id: TenantId,
      47              :     pub shard_number: ShardNumber,
      48              :     pub shard_count: ShardCount,
      49              : }
      50              : 
      51              : impl ShardCount {
      52              :     pub const MAX: Self = Self(u8::MAX);
      53              :     pub const MIN: Self = Self(0);
      54              : 
      55              :     /// The internal value of a ShardCount may be zero, which means "1 shard, but use
      56              :     /// legacy format for TenantShardId that excludes the shard suffix", also known
      57              :     /// as [`TenantShardId::unsharded`].
      58              :     ///
      59              :     /// This method returns the actual number of shards, i.e. if our internal value is
      60              :     /// zero, we return 1 (unsharded tenants have 1 shard).
      61      4809221 :     pub fn count(&self) -> u8 {
      62      4809221 :         if self.0 > 0 {
      63         5009 :             self.0
      64              :         } else {
      65      4804212 :             1
      66              :         }
      67      4809221 :     }
      68              : 
      69              :     /// The literal internal value: this is **not** the number of shards in the
      70              :     /// tenant, as we have a special zero value for legacy unsharded tenants.  Use
      71              :     /// [`Self::count`] if you want to know the cardinality of shards.
      72            2 :     pub fn literal(&self) -> u8 {
      73            2 :         self.0
      74            2 :     }
      75              : 
      76              :     /// Whether the `ShardCount` is for an unsharded tenant, so uses one shard but
      77              :     /// uses the legacy format for `TenantShardId`. See also the documentation for
      78              :     /// [`Self::count`].
      79            0 :     pub fn is_unsharded(&self) -> bool {
      80            0 :         self.0 == 0
      81            0 :     }
      82              : 
      83              :     /// `v` may be zero, or the number of shards in the tenant.  `v` is what
      84              :     /// [`Self::literal`] would return.
      85         9019 :     pub const fn new(val: u8) -> Self {
      86         9019 :         Self(val)
      87         9019 :     }
      88              : }
      89              : 
      90              : impl ShardNumber {
      91              :     pub const MAX: Self = Self(u8::MAX);
      92              : }
      93              : 
      94              : impl TenantShardId {
      95           39 :     pub fn unsharded(tenant_id: TenantId) -> Self {
      96           39 :         Self {
      97           39 :             tenant_id,
      98           39 :             shard_number: ShardNumber(0),
      99           39 :             shard_count: ShardCount(0),
     100           39 :         }
     101           39 :     }
     102              : 
     103              :     /// The range of all TenantShardId that belong to a particular TenantId.  This is useful when
     104              :     /// you have a BTreeMap of TenantShardId, and are querying by TenantId.
     105            0 :     pub fn tenant_range(tenant_id: TenantId) -> RangeInclusive<Self> {
     106            0 :         RangeInclusive::new(
     107            0 :             Self {
     108            0 :                 tenant_id,
     109            0 :                 shard_number: ShardNumber(0),
     110            0 :                 shard_count: ShardCount(0),
     111            0 :             },
     112            0 :             Self {
     113            0 :                 tenant_id,
     114            0 :                 shard_number: ShardNumber::MAX,
     115            0 :                 shard_count: ShardCount::MAX,
     116            0 :             },
     117            0 :         )
     118            0 :     }
     119              : 
     120        24271 :     pub fn shard_slug(&self) -> impl std::fmt::Display + '_ {
     121        24271 :         ShardSlug(self)
     122        24271 :     }
     123              : 
     124              :     /// Convenience for code that has special behavior on the 0th shard.
     125            6 :     pub fn is_shard_zero(&self) -> bool {
     126            6 :         self.shard_number == ShardNumber(0)
     127            6 :     }
     128              : 
     129              :     /// The "unsharded" value is distinct from simply having a single shard: it represents
     130              :     /// a tenant which is not shard-aware at all, and whose storage paths will not include
     131              :     /// a shard suffix.
     132            0 :     pub fn is_unsharded(&self) -> bool {
     133            0 :         self.shard_number == ShardNumber(0) && self.shard_count.is_unsharded()
     134            0 :     }
     135              : 
     136              :     /// Convenience for dropping the tenant_id and just getting the ShardIndex: this
     137              :     /// is useful when logging from code that is already in a span that includes tenant ID, to
     138              :     /// keep messages reasonably terse.
     139            0 :     pub fn to_index(&self) -> ShardIndex {
     140            0 :         ShardIndex {
     141            0 :             shard_number: self.shard_number,
     142            0 :             shard_count: self.shard_count,
     143            0 :         }
     144            0 :     }
     145              : 
     146              :     /// Calculate the children of this TenantShardId when splitting the overall tenant into
     147              :     /// the given number of shards.
     148            6 :     pub fn split(&self, new_shard_count: ShardCount) -> Vec<TenantShardId> {
     149            6 :         let effective_old_shard_count = std::cmp::max(self.shard_count.0, 1);
     150            6 :         let mut child_shards = Vec::new();
     151           32 :         for shard_number in 0..ShardNumber(new_shard_count.0).0 {
     152              :             // Key mapping is based on a round robin mapping of key hash modulo shard count,
     153              :             // so our child shards are the ones which the same keys would map to.
     154           32 :             if shard_number % effective_old_shard_count == self.shard_number.0 {
     155           28 :                 child_shards.push(TenantShardId {
     156           28 :                     tenant_id: self.tenant_id,
     157           28 :                     shard_number: ShardNumber(shard_number),
     158           28 :                     shard_count: new_shard_count,
     159           28 :                 })
     160            4 :             }
     161              :         }
     162              : 
     163            6 :         child_shards
     164            6 :     }
     165              : }
     166              : 
     167              : impl std::fmt::Display for ShardSlug<'_> {
     168        11712 :     fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
     169        11712 :         write!(
     170        11712 :             f,
     171        11712 :             "{:02x}{:02x}",
     172        11712 :             self.0.shard_number.0, self.0.shard_count.0
     173        11712 :         )
     174        11712 :     }
     175              : }
     176              : 
     177              : impl std::fmt::Display for TenantShardId {
     178        13243 :     fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
     179        13243 :         if self.shard_count != ShardCount(0) {
     180          153 :             write!(f, "{}-{}", self.tenant_id, self.shard_slug())
     181              :         } else {
     182              :             // Legacy case (shard_count == 0) -- format as just the tenant id.  Note that this
     183              :             // is distinct from the normal single shard case (shard count == 1).
     184        13090 :             self.tenant_id.fmt(f)
     185              :         }
     186        13243 :     }
     187              : }
     188              : 
     189              : impl std::fmt::Debug for TenantShardId {
     190         3128 :     fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
     191         3128 :         // Debug is the same as Display: the compact hex representation
     192         3128 :         write!(f, "{}", self)
     193         3128 :     }
     194              : }
     195              : 
     196              : impl std::str::FromStr for TenantShardId {
     197              :     type Err = hex::FromHexError;
     198              : 
     199         4451 :     fn from_str(s: &str) -> Result<Self, Self::Err> {
     200         4451 :         // Expect format: 16 byte TenantId, '-', 1 byte shard number, 1 byte shard count
     201         4451 :         if s.len() == 32 {
     202              :             // Legacy case: no shard specified
     203              :             Ok(Self {
     204         4415 :                 tenant_id: TenantId::from_str(s)?,
     205         4415 :                 shard_number: ShardNumber(0),
     206         4415 :                 shard_count: ShardCount(0),
     207              :             })
     208           36 :         } else if s.len() == 37 {
     209           36 :             let bytes = s.as_bytes();
     210           36 :             let tenant_id = TenantId::from_hex(&bytes[0..32])?;
     211           36 :             let mut shard_parts: [u8; 2] = [0u8; 2];
     212           36 :             hex::decode_to_slice(&bytes[33..37], &mut shard_parts)?;
     213           36 :             Ok(Self {
     214           36 :                 tenant_id,
     215           36 :                 shard_number: ShardNumber(shard_parts[0]),
     216           36 :                 shard_count: ShardCount(shard_parts[1]),
     217           36 :             })
     218              :         } else {
     219            0 :             Err(hex::FromHexError::InvalidStringLength)
     220              :         }
     221         4451 :     }
     222              : }
     223              : 
     224              : impl From<[u8; 18]> for TenantShardId {
     225            2 :     fn from(b: [u8; 18]) -> Self {
     226            2 :         let tenant_id_bytes: [u8; 16] = b[0..16].try_into().unwrap();
     227            2 : 
     228            2 :         Self {
     229            2 :             tenant_id: TenantId::from(tenant_id_bytes),
     230            2 :             shard_number: ShardNumber(b[16]),
     231            2 :             shard_count: ShardCount(b[17]),
     232            2 :         }
     233            2 :     }
     234              : }
     235              : 
     236              : impl ShardIndex {
     237            0 :     pub fn new(number: ShardNumber, count: ShardCount) -> Self {
     238            0 :         Self {
     239            0 :             shard_number: number,
     240            0 :             shard_count: count,
     241            0 :         }
     242            0 :     }
     243          102 :     pub fn unsharded() -> Self {
     244          102 :         Self {
     245          102 :             shard_number: ShardNumber(0),
     246          102 :             shard_count: ShardCount(0),
     247          102 :         }
     248          102 :     }
     249              : 
     250              :     /// The "unsharded" value is distinct from simply having a single shard: it represents
     251              :     /// a tenant which is not shard-aware at all, and whose storage paths will not include
     252              :     /// a shard suffix.
     253        72263 :     pub fn is_unsharded(&self) -> bool {
     254        72263 :         self.shard_number == ShardNumber(0) && self.shard_count == ShardCount(0)
     255        72263 :     }
     256              : 
     257              :     /// For use in constructing remote storage paths: concatenate this with a TenantId
     258              :     /// to get a fully qualified TenantShardId.
     259              :     ///
     260              :     /// Backward compat: this function returns an empty string if Self::is_unsharded, such
     261              :     /// that the legacy pre-sharding remote key format is preserved.
     262         1455 :     pub fn get_suffix(&self) -> String {
     263         1455 :         if self.is_unsharded() {
     264         1447 :             "".to_string()
     265              :         } else {
     266            8 :             format!("-{:02x}{:02x}", self.shard_number.0, self.shard_count.0)
     267              :         }
     268         1455 :     }
     269              : }
     270              : 
     271              : impl std::fmt::Display for ShardIndex {
     272         2038 :     fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
     273         2038 :         write!(f, "{:02x}{:02x}", self.shard_number.0, self.shard_count.0)
     274         2038 :     }
     275              : }
     276              : 
     277              : impl std::fmt::Debug for ShardIndex {
     278         1538 :     fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
     279         1538 :         // Debug is the same as Display: the compact hex representation
     280         1538 :         write!(f, "{}", self)
     281         1538 :     }
     282              : }
     283              : 
     284              : impl std::str::FromStr for ShardIndex {
     285              :     type Err = hex::FromHexError;
     286              : 
     287         3129 :     fn from_str(s: &str) -> Result<Self, Self::Err> {
     288         3129 :         // Expect format: 1 byte shard number, 1 byte shard count
     289         3129 :         if s.len() == 4 {
     290         3129 :             let bytes = s.as_bytes();
     291         3129 :             let mut shard_parts: [u8; 2] = [0u8; 2];
     292         3129 :             hex::decode_to_slice(bytes, &mut shard_parts)?;
     293         3129 :             Ok(Self {
     294         3129 :                 shard_number: ShardNumber(shard_parts[0]),
     295         3129 :                 shard_count: ShardCount(shard_parts[1]),
     296         3129 :             })
     297              :         } else {
     298            0 :             Err(hex::FromHexError::InvalidStringLength)
     299              :         }
     300         3129 :     }
     301              : }
     302              : 
     303              : impl From<[u8; 2]> for ShardIndex {
     304            1 :     fn from(b: [u8; 2]) -> Self {
     305            1 :         Self {
     306            1 :             shard_number: ShardNumber(b[0]),
     307            1 :             shard_count: ShardCount(b[1]),
     308            1 :         }
     309            1 :     }
     310              : }
     311              : 
     312              : impl Serialize for TenantShardId {
     313           46 :     fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
     314           46 :     where
     315           46 :         S: serde::Serializer,
     316           46 :     {
     317           46 :         if serializer.is_human_readable() {
     318           42 :             serializer.collect_str(self)
     319              :         } else {
     320              :             // Note: while human encoding of [`TenantShardId`] is backward and forward
     321              :             // compatible, this binary encoding is not.
     322            4 :             let mut packed: [u8; 18] = [0; 18];
     323            4 :             packed[0..16].clone_from_slice(&self.tenant_id.as_arr());
     324            4 :             packed[16] = self.shard_number.0;
     325            4 :             packed[17] = self.shard_count.0;
     326            4 : 
     327            4 :             packed.serialize(serializer)
     328              :         }
     329           46 :     }
     330              : }
     331              : 
     332              : impl<'de> Deserialize<'de> for TenantShardId {
     333            9 :     fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
     334            9 :     where
     335            9 :         D: serde::Deserializer<'de>,
     336            9 :     {
     337              :         struct IdVisitor {
     338              :             is_human_readable_deserializer: bool,
     339              :         }
     340              : 
     341              :         impl<'de> serde::de::Visitor<'de> for IdVisitor {
     342              :             type Value = TenantShardId;
     343              : 
     344            0 :             fn expecting(&self, formatter: &mut std::fmt::Formatter) -> std::fmt::Result {
     345            0 :                 if self.is_human_readable_deserializer {
     346            0 :                     formatter.write_str("value in form of hex string")
     347              :                 } else {
     348            0 :                     formatter.write_str("value in form of integer array([u8; 18])")
     349              :                 }
     350            0 :             }
     351              : 
     352            2 :             fn visit_seq<A>(self, seq: A) -> Result<Self::Value, A::Error>
     353            2 :             where
     354            2 :                 A: serde::de::SeqAccess<'de>,
     355            2 :             {
     356            2 :                 let s = serde::de::value::SeqAccessDeserializer::new(seq);
     357            2 :                 let id: [u8; 18] = Deserialize::deserialize(s)?;
     358            2 :                 Ok(TenantShardId::from(id))
     359            2 :             }
     360              : 
     361            7 :             fn visit_str<E>(self, v: &str) -> Result<Self::Value, E>
     362            7 :             where
     363            7 :                 E: serde::de::Error,
     364            7 :             {
     365            7 :                 TenantShardId::from_str(v).map_err(E::custom)
     366            7 :             }
     367              :         }
     368              : 
     369            9 :         if deserializer.is_human_readable() {
     370            7 :             deserializer.deserialize_str(IdVisitor {
     371            7 :                 is_human_readable_deserializer: true,
     372            7 :             })
     373              :         } else {
     374            2 :             deserializer.deserialize_tuple(
     375            2 :                 18,
     376            2 :                 IdVisitor {
     377            2 :                     is_human_readable_deserializer: false,
     378            2 :                 },
     379            2 :             )
     380              :         }
     381            9 :     }
     382              : }
     383              : 
     384              : impl Serialize for ShardIndex {
     385           18 :     fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
     386           18 :     where
     387           18 :         S: serde::Serializer,
     388           18 :     {
     389           18 :         if serializer.is_human_readable() {
     390           16 :             serializer.collect_str(self)
     391              :         } else {
     392              :             // Binary encoding is not used in index_part.json, but is included in anticipation of
     393              :             // switching various structures (e.g. inter-process communication, remote metadata) to more
     394              :             // compact binary encodings in future.
     395            2 :             let mut packed: [u8; 2] = [0; 2];
     396            2 :             packed[0] = self.shard_number.0;
     397            2 :             packed[1] = self.shard_count.0;
     398            2 :             packed.serialize(serializer)
     399              :         }
     400           18 :     }
     401              : }
     402              : 
     403              : impl<'de> Deserialize<'de> for ShardIndex {
     404         3129 :     fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
     405         3129 :     where
     406         3129 :         D: serde::Deserializer<'de>,
     407         3129 :     {
     408              :         struct IdVisitor {
     409              :             is_human_readable_deserializer: bool,
     410              :         }
     411              : 
     412              :         impl<'de> serde::de::Visitor<'de> for IdVisitor {
     413              :             type Value = ShardIndex;
     414              : 
     415            0 :             fn expecting(&self, formatter: &mut std::fmt::Formatter) -> std::fmt::Result {
     416            0 :                 if self.is_human_readable_deserializer {
     417            0 :                     formatter.write_str("value in form of hex string")
     418              :                 } else {
     419            0 :                     formatter.write_str("value in form of integer array([u8; 2])")
     420              :                 }
     421            0 :             }
     422              : 
     423            1 :             fn visit_seq<A>(self, seq: A) -> Result<Self::Value, A::Error>
     424            1 :             where
     425            1 :                 A: serde::de::SeqAccess<'de>,
     426            1 :             {
     427            1 :                 let s = serde::de::value::SeqAccessDeserializer::new(seq);
     428            1 :                 let id: [u8; 2] = Deserialize::deserialize(s)?;
     429            1 :                 Ok(ShardIndex::from(id))
     430            1 :             }
     431              : 
     432         3128 :             fn visit_str<E>(self, v: &str) -> Result<Self::Value, E>
     433         3128 :             where
     434         3128 :                 E: serde::de::Error,
     435         3128 :             {
     436         3128 :                 ShardIndex::from_str(v).map_err(E::custom)
     437         3128 :             }
     438              :         }
     439              : 
     440         3129 :         if deserializer.is_human_readable() {
     441         3128 :             deserializer.deserialize_str(IdVisitor {
     442         3128 :                 is_human_readable_deserializer: true,
     443         3128 :             })
     444              :         } else {
     445            1 :             deserializer.deserialize_tuple(
     446            1 :                 2,
     447            1 :                 IdVisitor {
     448            1 :                     is_human_readable_deserializer: false,
     449            1 :                 },
     450            1 :             )
     451              :         }
     452         3129 :     }
     453              : }
        

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