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use std ::path ::PathBuf ;
use serde ::{ Deserialize , Serialize } ;
use garage_util ::config ::DataDirEnum ;
use garage_util ::data ::Hash ;
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use garage_util ::error ::{ Error , OkOrMessage } ;
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use garage_util ::migrate ::* ;
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type Idx = u16 ;
const DRIVE_NPART : usize = 1024 ;
const DPART_BYTES : ( usize , usize ) = ( 2 , 3 ) ;
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#[ derive(Serialize, Deserialize, Debug, Clone) ]
pub ( crate ) struct DataLayout {
pub ( crate ) data_dirs : Vec < DataDir > ,
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/// Primary storage location (index in data_dirs) for each partition
pub ( crate ) part_prim : Vec < Idx > ,
/// Secondary storage locations for each partition
pub ( crate ) part_sec : Vec < Vec < Idx > > ,
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}
#[ derive(Serialize, Deserialize, Debug, Clone) ]
pub ( crate ) struct DataDir {
pub ( crate ) path : PathBuf ,
pub ( crate ) state : DataDirState ,
}
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#[ derive(Serialize, Deserialize, Debug, Clone, Copy) ]
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pub ( crate ) enum DataDirState {
Active { capacity : u64 } ,
ReadOnly ,
}
impl DataLayout {
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pub ( crate ) fn initialize ( dirs : & DataDirEnum ) -> Result < Self , Error > {
let data_dirs = make_data_dirs ( dirs ) ? ;
// Split partitions proportionnally to capacity for all drives
// to affect primary storage location
let total_cap = data_dirs . iter ( ) . filter_map ( | x | x . capacity ( ) ) . sum ::< u64 > ( ) ;
let mut part_prim = Vec ::with_capacity ( DRIVE_NPART ) ;
let mut cum_cap = 0 ;
for ( i , dd ) in data_dirs . iter ( ) . enumerate ( ) {
if let DataDirState ::Active { capacity } = dd . state {
cum_cap + = capacity ;
let n_total = ( cum_cap * DRIVE_NPART as u64 ) / total_cap ;
part_prim . resize ( n_total as usize , i as Idx ) ;
}
}
assert_eq! ( cum_cap , total_cap ) ;
assert_eq! ( part_prim . len ( ) , DRIVE_NPART ) ;
// If any of the storage locations is non-empty, add it as a secondary
// storage location for all partitions
let mut part_sec = vec! [ vec! [ ] ; DRIVE_NPART ] ;
for ( i , dd ) in data_dirs . iter ( ) . enumerate ( ) {
if dir_not_empty ( & dd . path ) ? {
for ( sec , prim ) in part_sec . iter_mut ( ) . zip ( part_prim . iter ( ) ) {
if * prim ! = i as Idx {
sec . push ( i as Idx ) ;
}
}
}
}
Ok ( Self {
data_dirs ,
part_prim ,
part_sec ,
} )
}
pub ( crate ) fn update ( & mut self , dirs : & DataDirEnum ) -> Result < Self , Error > {
// Compute list of new data directories and mapping of old indices
// to new indices
let data_dirs = make_data_dirs ( dirs ) ? ;
let old2new = self
. data_dirs
. iter ( )
. map ( | x | {
data_dirs
. iter ( )
. position ( | y | y . path = = x . path )
. map ( | x | x as Idx )
} )
. collect ::< Vec < _ > > ( ) ;
// Compute secondary location list for partitions based on existing
// folders, translating indices from old to new
let mut part_sec = self
. part_sec
. iter ( )
. map ( | dl | {
dl . iter ( )
. filter_map ( | old | old2new . get ( * old as usize ) . copied ( ) . flatten ( ) )
. collect ::< Vec < _ > > ( )
} )
. collect ::< Vec < _ > > ( ) ;
// Compute a vector that, for each data dir,
// contains the list of partitions primarily stored on that drive
let mut dir_prim = vec! [ vec! [ ] ; data_dirs . len ( ) ] ;
for ( ipart , prim ) in self . part_prim . iter ( ) . enumerate ( ) {
if let Some ( new ) = old2new . get ( * prim as usize ) . copied ( ) . flatten ( ) {
dir_prim [ new as usize ] . push ( ipart ) ;
}
}
// Compute the target number of partitions per data directory
let total_cap = data_dirs . iter ( ) . filter_map ( | x | x . capacity ( ) ) . sum ::< u64 > ( ) ;
let mut cum_cap = 0 ;
let mut npart_per_dir = vec! [ ] ;
for dd in data_dirs . iter ( ) {
if let DataDirState ::Active { capacity } = dd . state {
let begin = ( cum_cap * DRIVE_NPART as u64 ) / total_cap ;
cum_cap + = capacity ;
let end = ( cum_cap * DRIVE_NPART as u64 ) / total_cap ;
npart_per_dir . push ( ( end - begin ) as usize ) ;
} else {
npart_per_dir . push ( 0 ) ;
}
}
assert_eq! ( cum_cap , total_cap ) ;
assert_eq! ( npart_per_dir . iter ( ) . sum ::< usize > ( ) , DRIVE_NPART ) ;
// For all directories that have too many primary partitions,
// move that partition to secondary
for ( idir , ( parts , tgt_npart ) ) in dir_prim . iter_mut ( ) . zip ( npart_per_dir . iter ( ) ) . enumerate ( )
{
while parts . len ( ) > * tgt_npart {
let part = parts . pop ( ) . unwrap ( ) ;
if ! part_sec [ part ] . contains ( & ( idir as Idx ) ) {
part_sec [ part ] . push ( idir as Idx ) ;
}
}
}
// Calculate the vector of primary partition dir index
let mut part_prim = vec! [ None ; DRIVE_NPART ] ;
for ( idir , parts ) in dir_prim . iter ( ) . enumerate ( ) {
for part in parts . iter ( ) {
assert! ( part_prim [ * part ] . is_none ( ) ) ;
part_prim [ * part ] = Some ( idir as Idx )
}
}
// Calculate a vector of unassigned partitions
let mut unassigned = part_prim
. iter ( )
. enumerate ( )
. filter ( | ( _ , dir ) | dir . is_none ( ) )
. map ( | ( ipart , _ ) | ipart )
. collect ::< Vec < _ > > ( ) ;
// For all directories that don't have enough primary partitions,
// add partitions from unassigned
for ( idir , ( parts , tgt_npart ) ) in dir_prim . iter_mut ( ) . zip ( npart_per_dir . iter ( ) ) . enumerate ( )
{
assert! ( unassigned . len ( ) > = * tgt_npart - parts . len ( ) ) ;
for _ in parts . len ( ) .. * tgt_npart {
let new_part = unassigned . pop ( ) . unwrap ( ) ;
part_prim [ new_part ] = Some ( idir as Idx ) ;
part_sec [ new_part ] . retain ( | x | * x ! = idir as Idx ) ;
}
}
// Sanity checks
assert! ( part_prim . iter ( ) . all ( | x | x . is_some ( ) ) ) ;
assert! ( unassigned . is_empty ( ) ) ;
let part_prim = part_prim
. into_iter ( )
. map ( | x | x . unwrap ( ) )
. collect ::< Vec < _ > > ( ) ;
assert! ( part_prim . iter ( ) . all ( | p | data_dirs
. get ( * p as usize )
. and_then ( | x | x . capacity ( ) )
. unwrap_or ( 0 )
> 0 ) ) ;
Ok ( Self {
data_dirs ,
part_prim ,
part_sec ,
} )
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}
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pub ( crate ) fn primary_block_dir ( & self , hash : & Hash ) -> PathBuf {
let ipart = self . partition_from ( hash ) ;
let idir = self . part_prim [ ipart ] as usize ;
self . block_dir_from ( hash , & self . data_dirs [ idir ] . path )
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}
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pub ( crate ) fn secondary_block_dirs < ' a > (
& ' a self ,
hash : & ' a Hash ,
) -> impl Iterator < Item = PathBuf > + ' a {
let ipart = self . partition_from ( hash ) ;
self . part_sec [ ipart ]
. iter ( )
. map ( move | idir | self . block_dir_from ( hash , & self . data_dirs [ * idir as usize ] . path ) )
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}
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fn partition_from ( & self , hash : & Hash ) -> usize {
u16 ::from_be_bytes ( [
hash . as_slice ( ) [ DPART_BYTES . 0 ] ,
hash . as_slice ( ) [ DPART_BYTES . 1 ] ,
] ) as usize % DRIVE_NPART
}
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fn block_dir_from ( & self , hash : & Hash , dir : & PathBuf ) -> PathBuf {
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let mut path = dir . clone ( ) ;
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path . push ( hex ::encode ( & hash . as_slice ( ) [ 0 .. 1 ] ) ) ;
path . push ( hex ::encode ( & hash . as_slice ( ) [ 1 .. 2 ] ) ) ;
path
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}
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}
impl InitialFormat for DataLayout {
const VERSION_MARKER : & 'static [ u8 ] = b " G09bmdl " ;
}
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impl DataDir {
pub fn capacity ( & self ) -> Option < u64 > {
match self . state {
DataDirState ::Active { capacity } = > Some ( capacity ) ,
_ = > None ,
}
}
}
fn make_data_dirs ( dirs : & DataDirEnum ) -> Result < Vec < DataDir > , Error > {
let mut data_dirs = vec! [ ] ;
match dirs {
DataDirEnum ::Single ( path ) = > data_dirs . push ( DataDir {
path : path . clone ( ) ,
state : DataDirState ::Active {
capacity : 1_000_000_000 , // whatever, doesn't matter
} ,
} ) ,
DataDirEnum ::Multiple ( dirs ) = > {
for dir in dirs . iter ( ) {
let state = match & dir . capacity {
Some ( cap ) if dir . read_only = = false = > {
DataDirState ::Active {
capacity : cap . parse ::< bytesize ::ByteSize > ( )
. ok_or_message ( " invalid capacity value " ) ? . as_u64 ( ) ,
}
}
None if dir . read_only = = true = > {
DataDirState ::ReadOnly
}
_ = > return Err ( Error ::Message ( format! ( " data directories in data_dir should have a capacity value or be marked read_only, not the case for {} " , dir . path . to_string_lossy ( ) ) ) ) ,
} ;
data_dirs . push ( DataDir {
path : dir . path . clone ( ) ,
state ,
} ) ;
}
}
}
Ok ( data_dirs )
}
fn dir_not_empty ( path : & PathBuf ) -> Result < bool , Error > {
for entry in std ::fs ::read_dir ( & path ) ? {
let dir = entry ? ;
if dir . file_type ( ) ? . is_dir ( )
& & dir
. file_name ( )
. into_string ( )
. ok ( )
. and_then ( | hex | hex ::decode ( & hex ) . ok ( ) )
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. is_some ( )
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{
return Ok ( true ) ;
}
}
Ok ( false )
}