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Copy pathBelt_HashMapString.res
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Belt_HashMapString.res
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/* ********************************************************************* */
/* */
/* OCaml */
/* */
/* Xavier Leroy, projet Cristal, INRIA Rocquencourt */
/* */
/* Copyright 1996 Institut National de Recherche en Informatique et */
/* en Automatique. All rights reserved. This file is distributed */
/* under the terms of the GNU Library General Public License, with */
/* the special exception on linking described in file ../LICENSE. */
/* */
/* ********************************************************************* */
/* Adapted by Hongbo Zhang, Authors of ReScript 2017 */
type key = string
type seed = int
external hash_mix_string: (seed, string) => seed = "%hash_mix_string"
external hash_final_mix: seed => seed = "%hash_final_mix"
let hash = (s: key) => hash_final_mix(hash_mix_string(0, s))
module N = Belt_internalBuckets
module C = Belt_internalBucketsType
module A = Belt_Array
type t<'b> = N.t<unit, unit, key, 'b>
let rec copyBucketReHash = (~h_buckets, ~ndata_tail, old_bucket: C.opt<N.bucket<_>>) =>
switch C.toOpt(old_bucket) {
| None => ()
| Some(cell) =>
let nidx = land(hash(cell.key), A.length(h_buckets) - 1)
let v = C.return(cell)
switch C.toOpt(A.getUnsafe(ndata_tail, nidx)) {
| None => A.setUnsafe(h_buckets, nidx, v)
| Some(tail) => tail.N.next = v /* cell put at the end */
}
A.setUnsafe(ndata_tail, nidx, v)
copyBucketReHash(~h_buckets, ~ndata_tail, cell.next)
}
let resize = h => {
let odata = h.C.buckets
let osize = A.length(odata)
let nsize = osize * 2
if nsize >= osize {
/* no overflow */
let h_buckets = A.makeUninitialized(nsize)
let ndata_tail = A.makeUninitialized(nsize) /* keep track of tail */
h.C.buckets = h_buckets /* so that indexfun sees the new bucket count */
for i in 0 to osize - 1 {
copyBucketReHash(~h_buckets, ~ndata_tail, A.getUnsafe(odata, i))
}
for i in 0 to nsize - 1 {
switch C.toOpt(A.getUnsafe(ndata_tail, i)) {
| None => ()
| Some(tail) => tail.next = C.emptyOpt
}
}
}
}
let rec replaceInBucket = (key: key, info, cell) =>
if cell.N.key == key {
cell.N.value = info
false
} else {
switch C.toOpt(cell.next) {
| None => true
| Some(cell) => replaceInBucket(key, info, cell)
}
}
let set = (h, key: key, value) => {
let h_buckets = h.C.buckets
let buckets_len = A.length(h_buckets)
let i = land(hash(key), buckets_len - 1)
let l = A.getUnsafe(h_buckets, i)
switch C.toOpt(l) {
| None =>
A.setUnsafe(h_buckets, i, C.return({N.key, value, next: C.emptyOpt}))
h.C.size = h.C.size + 1
| Some(bucket) =>
if replaceInBucket(key, value, bucket) {
A.setUnsafe(h_buckets, i, C.return({N.key, value, next: l}))
h.C.size = h.C.size + 1
}
}
if h.C.size > lsl(buckets_len, 1) {
resize(h)
}
}
let rec removeInBucket = (h, h_buckets, i, key: key, prec, buckets) =>
switch C.toOpt(buckets) {
| None => ()
| Some(cell) =>
let cell_next = cell.N.next
if cell.N.key == key {
prec.N.next = cell_next
h.C.size = h.C.size - 1
} else {
removeInBucket(h, h_buckets, i, key, cell, cell_next)
}
}
let remove = (h, key) => {
let h_buckets = h.C.buckets
let i = land(hash(key), A.length(h_buckets) - 1)
let bucket = A.getUnsafe(h_buckets, i)
switch C.toOpt(bucket) {
| None => ()
| Some(cell) =>
if cell.N.key == key {
A.setUnsafe(h_buckets, i, cell.next)
h.C.size = h.C.size - 1
} else {
removeInBucket(h, h_buckets, i, key, cell, cell.next)
}
}
}
let rec getAux = (key: key, buckets) =>
switch C.toOpt(buckets) {
| None => None
| Some(cell) =>
if key == cell.N.key {
Some(cell.N.value)
} else {
getAux(key, cell.next)
}
}
let get = (h, key: key) => {
let h_buckets = h.C.buckets
let nid = land(hash(key), A.length(h_buckets) - 1)
switch C.toOpt(A.getUnsafe(h_buckets, nid)) {
| None => None
| Some(cell1) =>
if key == cell1.N.key {
Some(cell1.N.value)
} else {
switch C.toOpt(cell1.N.next) {
| None => None
| Some(cell2) =>
if key == cell2.N.key {
Some(cell2.N.value)
} else {
switch C.toOpt(cell2.N.next) {
| None => None
| Some(cell3) =>
if key == cell3.N.key {
Some(cell3.N.value)
} else {
getAux(key, cell3.N.next)
}
}
}
}
}
}
}
let rec memInBucket = (key: key, cell) =>
cell.N.key == key ||
switch C.toOpt(cell.next) {
| None => false
| Some(nextCell) => memInBucket(key, nextCell)
}
let has = (h, key) => {
let h_buckets = h.C.buckets
let nid = land(hash(key), A.length(h_buckets) - 1)
let bucket = A.getUnsafe(h_buckets, nid)
switch C.toOpt(bucket) {
| None => false
| Some(bucket) => memInBucket(key, bucket)
}
}
let make = (~hintSize) => C.make(~hintSize, ~hash=(), ~eq=())
let clear = C.clear
let size = h => h.C.size
let forEach = N.forEach
let reduce = N.reduce
let logStats = N.logStats
let keepMapInPlace = N.keepMapInPlace
let toArray = N.toArray
let copy = N.copy
let keysToArray = N.keysToArray
let valuesToArray = N.valuesToArray
let getBucketHistogram = N.getBucketHistogram
let isEmpty = C.isEmpty
let fromArray = arr => {
let len = A.length(arr)
let v = make(~hintSize=len)
for i in 0 to len - 1 {
let (k, value) = A.getUnsafe(arr, i)
set(v, k, value)
}
v
}
/* TOOD: optimize heuristics for resizing */
let mergeMany = (h, arr) => {
let len = A.length(arr)
for i in 0 to len - 1 {
let (k, v) = A.getUnsafe(arr, i)
set(h, k, v)
}
}
let forEachU = forEach
let reduceU = reduce
let keepMapInPlaceU = keepMapInPlace