module Hashtbl: Hashtbl;
type t('a, 'b);
The type of hash tables from type 'a
to type 'b
.
let create: (~random: bool=?, int) => t('a, 'b);
Hashtbl.create n
creates a new, empty hash table, with
initial size n
. For best results, n
should be on the
order of the expected number of elements that will be in
the table. The table grows as needed, so n
is just an
initial guess.
The optional ~
random
parameter (a boolean) controls whether
the internal organization of the hash table is randomized at each
execution of Hashtbl.create
or deterministic over all executions.
A hash table that is created with ~
random
set to false
uses a
fixed hash function (Hashtbl.hash
) to distribute keys among
buckets. As a consequence, collisions between keys happen
deterministically. In Web-facing applications or other
security-sensitive applications, the deterministic collision
patterns can be exploited by a malicious user to create a
denial-of-service attack: the attacker sends input crafted to
create many collisions in the table, slowing the application down.
A hash table that is created with ~
random
set to true
uses the seeded
hash function Hashtbl.seeded_hash
with a seed that is randomly chosen at hash
table creation time. In effect, the hash function used is randomly
selected among 2^{30}
different hash functions. All these hash
functions have different collision patterns, rendering ineffective the
denial-of-service attack described above. However, because of
randomization, enumerating all elements of the hash table using Hashtbl.fold
or Hashtbl.iter
is no longer deterministic: elements are enumerated in
different orders at different runs of the program.
If no ~
random
parameter is given, hash tables are created
in non-random mode by default. This default can be changed
either programmatically by calling Hashtbl.randomize
or by
setting the R
flag in the OCAMLRUNPARAM
environment variable.
~
random
parameter was not present and all
hash tables were created in non-randomized mode.let clear: t('a, 'b) => unit;
Empty a hash table. Use reset
instead of clear
to shrink the
size of the bucket table to its initial size.
let reset: t('a, 'b) => unit;
Empty a hash table and shrink the size of the bucket table to its initial size.
let copy: t('a, 'b) => t('a, 'b);
Return a copy of the given hashtable.
let add: (t('a, 'b), 'a, 'b) => unit;
Hashtbl.add tbl key data
adds a binding of key
to data
in table tbl
.
Previous bindings for key
are not removed, but simply
hidden. That is, after performing Hashtbl.remove
tbl key
,
the previous binding for key
, if any, is restored.
(Same behavior as with association lists.)
let find: (t('a, 'b), 'a) => 'b;
Hashtbl.find tbl x
returns the current binding of x
in tbl
,
or raises Not_found
if no such binding exists.
let find_opt: (t('a, 'b), 'a) => option('b);
Hashtbl.find_opt tbl x
returns the current binding of x
in tbl
,
or None
if no such binding exists.
let find_all: (t('a, 'b), 'a) => list('b);
Hashtbl.find_all tbl x
returns the list of all data
associated with x
in tbl
.
The current binding is returned first, then the previous
bindings, in reverse order of introduction in the table.
let mem: (t('a, 'b), 'a) => bool;
Hashtbl.mem tbl x
checks if x
is bound in tbl
.
let remove: (t('a, 'b), 'a) => unit;
Hashtbl.remove tbl x
removes the current binding of x
in tbl
,
restoring the previous binding if it exists.
It does nothing if x
is not bound in tbl
.
let replace: (t('a, 'b), 'a, 'b) => unit;
Hashtbl.replace tbl key data
replaces the current binding of key
in tbl
by a binding of key
to data
. If key
is unbound in tbl
,
a binding of key
to data
is added to tbl
.
This is functionally equivalent to Hashtbl.remove
tbl key
followed by Hashtbl.add
tbl key data
.
let iter: (('a, 'b) => unit, t('a, 'b)) => unit;
Hashtbl.iter f tbl
applies f
to all bindings in table tbl
.
f
receives the key as first argument, and the associated value
as second argument. Each binding is presented exactly once to f
.
The order in which the bindings are passed to f
is unspecified.
However, if the table contains several bindings for the same key,
they are passed to f
in reverse order of introduction, that is,
the most recent binding is passed first.
If the hash table was created in non-randomized mode, the order in which the bindings are enumerated is reproducible between successive runs of the program, and even between minor versions of OCaml. For randomized hash tables, the order of enumeration is entirely random.
The behavior is not defined if the hash table is modified
by f
during the iteration.
let filter_map_inplace: (('a, 'b) => option('b), t('a, 'b)) => unit;
Hashtbl.filter_map_inplace f tbl
applies f
to all bindings in
table tbl
and update each binding depending on the result of
f
. If f
returns None
, the binding is discarded. If it
returns Some new_val
, the binding is update to associate the key
to new_val
.
Other comments for Hashtbl.iter
apply as well.
let fold: (('a, 'b, 'c) => 'c, t('a, 'b), 'c) => 'c;
Hashtbl.fold f tbl init
computes
(f kN dN ... (f k1 d1 init)...)
,
where k1 ... kN
are the keys of all bindings in tbl
,
and d1 ... dN
are the associated values.
Each binding is presented exactly once to f
.
The order in which the bindings are passed to f
is unspecified.
However, if the table contains several bindings for the same key,
they are passed to f
in reverse order of introduction, that is,
the most recent binding is passed first.
If the hash table was created in non-randomized mode, the order in which the bindings are enumerated is reproducible between successive runs of the program, and even between minor versions of OCaml. For randomized hash tables, the order of enumeration is entirely random.
The behavior is not defined if the hash table is modified
by f
during the iteration.
let length: t('a, 'b) => int;
Hashtbl.length tbl
returns the number of bindings in tbl
.
It takes constant time. Multiple bindings are counted once each, so
Hashtbl.length
gives the number of times Hashtbl.iter
calls its
first argument.
let randomize: unit => unit;
After a call to Hashtbl.randomize()
, hash tables are created in
randomized mode by default: Hashtbl.create
returns randomized
hash tables, unless the ~random:false
optional parameter is given.
The same effect can be achieved by setting the R
parameter in
the OCAMLRUNPARAM
environment variable.
It is recommended that applications or Web frameworks that need to
protect themselves against the denial-of-service attack described
in Hashtbl.create
call Hashtbl.randomize()
at initialization
time.
Note that once Hashtbl.randomize()
was called, there is no way
to revert to the non-randomized default behavior of Hashtbl.create
.
This is intentional. Non-randomized hash tables can still be
created using Hashtbl.create ~random:false
.
let is_randomized: unit => bool;
Return true
if the tables are currently created in randomized mode
by default, false
otherwise.
let rebuild: (~random: bool=?, t('a, 'b)) => t('a, 'b);
Return a copy of the given hashtable. Unlike Hashtbl.copy
,
Hashtbl.rebuild
h
re-hashes all the (key, value) entries of
the original table h
. The returned hash table is randomized if
h
was randomized, or the optional random
parameter is true, or
if the default is to create randomized hash tables; see
Hashtbl.create
for more information.
Hashtbl.rebuild
can safely be used to import a hash table built
by an old version of the Hashtbl
module, then marshaled to
persistent storage. After unmarshaling, apply Hashtbl.rebuild
to produce a hash table for the current version of the Hashtbl
module.
type statistics = {
|
num_bindings : int; |
(* | Number of bindings present in the table.
Same value as returned by | *) |
|
num_buckets : int; |
(* | Number of buckets in the table. | *) |
|
max_bucket_length : int; |
(* | Maximal number of bindings per bucket. | *) |
|
bucket_histogram : int array; |
(* | Histogram of bucket sizes. This array | *) |
}
let stats: t('a, 'b) => statistics;
Hashtbl.stats tbl
returns statistics about the table tbl
:
number of buckets, size of the biggest bucket, distribution of
buckets by size.
let to_seq: t('a, 'b) => Seq.t(('a, 'b));
Iterate on the whole table. The order in which the bindings appear in the sequence is unspecified. However, if the table contains several bindings for the same key, they appear in reversed order of introduction, that is, the most recent binding appears first.
The behavior is not defined if the hash table is modified during the iteration.
let to_seq_keys: t('a, 'b) => Seq.t('a);
Same as Seq.map fst (to_seq m)
let to_seq_values: t('a, 'b) => Seq.t('b);
Same as Seq.map snd (to_seq m)
let add_seq: (t('a, 'b), Seq.t(('a, 'b))) => unit;
Add the given bindings to the table, using Hashtbl.add
let replace_seq: (t('a, 'b), Seq.t(('a, 'b))) => unit;
Add the given bindings to the table, using Hashtbl.replace
let of_seq: Seq.t(('a, 'b)) => t('a, 'b);
Build a table from the given bindings. The bindings are added
in the same order they appear in the sequence, using Hashtbl.replace_seq
,
which means that if two pairs have the same key, only the latest one
will appear in the table.
The functorial interface allows the use of specific comparison and hash functions, either for performance/security concerns, or because keys are not hashable/comparable with the polymorphic builtins.
For instance, one might want to specialize a table for integer keys:
module IntHash = struct type t = int let equal i j = i=j let hash i = i land max_int end module IntHashtbl = Hashtbl.Make(IntHash) let h = IntHashtbl.create 17 in IntHashtbl.add h 12 "hello"
This creates a new module IntHashtbl
, with a new type 'a
IntHashtbl.t
of tables from int
to 'a
. In this example, h
contains string
values so its type is string IntHashtbl.t
.
Note that the new type 'a IntHashtbl.t
is not compatible with
the type ('a,'b) Hashtbl.t
of the generic interface. For
example, Hashtbl.length h
would not type-check, you must use
IntHashtbl.length
.
module type HashedType = sig .. end
The input signature of the functor Hashtbl.Make
.
module type S = sig .. end
The output signature of the functor Hashtbl.Make
.
module Make: (H: HashedType) => S with type key = H.t;
Functor building an implementation of the hashtable structure.
module type SeededHashedType = sig .. end
The input signature of the functor Hashtbl.MakeSeeded
.
module type SeededS = sig .. end
The output signature of the functor Hashtbl.MakeSeeded
.
module MakeSeeded: (H: SeededHashedType) => SeededS with type key = H.t;
Functor building an implementation of the hashtable structure.
let hash: 'a => int;
Hashtbl.hash x
associates a nonnegative integer to any value of
any type. It is guaranteed that
if x = y
or Stdlib.compare x y = 0
, then hash x = hash y
.
Moreover, hash
always terminates, even on cyclic structures.
let seeded_hash: (int, 'a) => int;
A variant of Hashtbl.hash
that is further parameterized by
an integer seed.
let hash_param: (int, int, 'a) => int;
Hashtbl.hash_param meaningful total x
computes a hash value for x
,
with the same properties as for hash
. The two extra integer
parameters meaningful
and total
give more precise control over
hashing. Hashing performs a breadth-first, left-to-right traversal
of the structure x
, stopping after meaningful
meaningful nodes
were encountered, or total
nodes (meaningful or not) were
encountered. If total
as specified by the user exceeds a certain
value, currently 256, then it is capped to that value.
Meaningful nodes are: integers; floating-point
numbers; strings; characters; booleans; and constant
constructors. Larger values of meaningful
and total
means that
more nodes are taken into account to compute the final hash value,
and therefore collisions are less likely to happen. However,
hashing takes longer. The parameters meaningful
and total
govern the tradeoff between accuracy and speed. As default
choices, Hashtbl.hash
and Hashtbl.seeded_hash
take
meaningful = 10
and total = 100
.
let seeded_hash_param: (int, int, int, 'a) => int;
A variant of Hashtbl.hash_param
that is further parameterized by
an integer seed. Usage:
Hashtbl.seeded_hash_param meaningful total seed x
.