package core_kernel

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An Unsafe pool is like an ordinary pool, except that the create function does not require an initial element. The pool stores Obj.magic () as the dummy value for each slot. Such a pool is only safe if one never accesses a slot from a freed tuple.

It makes sense to use Unsafe if one has a small constrained chunk of code where one can prove that one never accesses a freed tuple, and one needs a pool where it is difficult to construct a dummy value.

Some Unsafe functions are faster than the corresponding safe version because they do not have to maintain values with the correct represention in the Obj_array backing the pool: free, create, grow.

An Unsafe pool is like an ordinary pool, except that the create function does not require an initial element. The pool stores Obj.magic () as the dummy value for each slot. Such a pool is only safe if one never accesses a slot from a freed tuple.

It makes sense to use Unsafe if one has a small constrained chunk of code where one can prove that one never accesses a freed tuple, and one needs a pool where it is difficult to construct a dummy value.

Some Unsafe functions are faster than the corresponding safe version because they do not have to maintain values with the correct represention in the Obj_array backing the pool: free, create, grow.

An Unsafe pool is like an ordinary pool, except that the create function does not require an initial element. The pool stores Obj.magic () as the dummy value for each slot. Such a pool is only safe if one never accesses a slot from a freed tuple.

It makes sense to use Unsafe if one has a small constrained chunk of code where one can prove that one never accesses a freed tuple, and one needs a pool where it is difficult to construct a dummy value.

Some Unsafe functions are faster than the corresponding safe version because they do not have to maintain values with the correct represention in the Obj_array backing the pool: free, create, grow.

include Pool.S with type 'a Pointer.t = private Base.Int.t
module Slots : sig ... end

Slots has types t1, ..., t12 of arities 1 to 12 that are isomorphic to tuple types of the corresponding arities. Type ('a0, ..., 'a<N-1>) t<N> corresponds to 'a0 * ... * 'a<N-1>.

module Slot : sig ... end
module Pointer : sig ... end
type 'slots t

A pool. 'slots will look like ('a1, ..., 'an) Slots.tn, and the pool holds tuples of type 'a1 * ... * 'an.

include sig ... end
val sexp_of_t : ('slots -> Sexplib.Sexp.t) -> 'slots t -> Sexplib.Sexp.t
include Base.Invariant.S1 with type 'a t := 'a t
val invariant : ('a -> unit) -> 'a t -> unit
val pointer_is_valid : 'slots t -> 'slots Pointer.t -> Base.Bool.t

pointer_is_valid t pointer returns true iff pointer points to a live tuple in t, i.e. pointer is not null, not free, and is in the range of t.

A pointer might not be in the range of a pool if it comes from another pool for example. In this case unsafe_get/set functions would cause a segfault.

val id_of_pointer : 'slots t -> 'slots Pointer.t -> Pointer.Id.t

id_of_pointer t pointer returns an id that is unique for the lifetime of pointer's tuple. When the tuple is freed, the id is no longer valid, and pointer_of_id_exn will fail on it. Pointer.null () has a distinct id from all non-null pointers.

val pointer_of_id_exn : 'slots t -> Pointer.Id.t -> 'slots Pointer.t

pointer_of_id_exn t id returns the pointer corresponding to id. It fails if the tuple corresponding to id was already freed.

val max_capacity : slots_per_tuple:Base.Int.t -> Base.Int.t

max_capacity returns the maximum capacity allowed when creating a pool.

val capacity : _ t -> Base.Int.t

capacity returns the maximum number of tuples that the pool can hold.

val length : _ t -> Base.Int.t

length returns the number of tuples currently in the pool.

0 <= length t <= capacity t
val grow : ?capacity:Base.Int.t -> 'a t -> 'a t

grow t ~capacity returns a new pool t' with the supplied capacity. The new pool is to be used as a replacement for t. All live tuples in t are now live in t', and valid pointers to tuples in t are now valid pointers to the identical tuple in t'. It is an error to use t after calling grow t.

grow raises if the supplied capacity isn't larger than capacity t.

val is_full : _ t -> Base.Bool.t

is_full t returns true if no more tuples can be allocated in t.

val free : 'slots t -> 'slots Pointer.t -> Base.Unit.t

free t pointer frees the tuple pointed to by pointer from t.

val unsafe_free : 'slots t -> 'slots Pointer.t -> Base.Unit.t

unsafe_free t pointer frees the tuple pointed to by pointer without checking pointer_is_valid

val new1 : 'a0 Slots.t1 as 'slots t -> 'a0 -> 'slots Pointer.t

new<N> t a0 ... a<N-1> returns a new tuple from the pool, with the tuple's slots initialized to a0 ... a<N-1>. new raises if is_full t.

val new2 : ('a0, 'a1) Slots.t2 as 'slots t -> 'a0 -> 'a1 -> 'slots Pointer.t
val new3 : ('a0, 'a1, 'a2) Slots.t3 as 'slots t -> 'a0 -> 'a1 -> 'a2 -> 'slots Pointer.t
val new4 : ('a0, 'a1, 'a2, 'a3) Slots.t4 as 'slots t -> 'a0 -> 'a1 -> 'a2 -> 'a3 -> 'slots Pointer.t
val new5 : ('a0, 'a1, 'a2, 'a3, 'a4) Slots.t5 as 'slots t -> 'a0 -> 'a1 -> 'a2 -> 'a3 -> 'a4 -> 'slots Pointer.t
val new6 : ('a0, 'a1, 'a2, 'a3, 'a4, 'a5) Slots.t6 as 'slots t -> 'a0 -> 'a1 -> 'a2 -> 'a3 -> 'a4 -> 'a5 -> 'slots Pointer.t
val new7 : ('a0, 'a1, 'a2, 'a3, 'a4, 'a5, 'a6) Slots.t7 as 'slots t -> 'a0 -> 'a1 -> 'a2 -> 'a3 -> 'a4 -> 'a5 -> 'a6 -> 'slots Pointer.t
val new8 : ('a0, 'a1, 'a2, 'a3, 'a4, 'a5, 'a6, 'a7) Slots.t8 as 'slots t -> 'a0 -> 'a1 -> 'a2 -> 'a3 -> 'a4 -> 'a5 -> 'a6 -> 'a7 -> 'slots Pointer.t
val new9 : ('a0, 'a1, 'a2, 'a3, 'a4, 'a5, 'a6, 'a7, 'a8) Slots.t9 as 'slots t -> 'a0 -> 'a1 -> 'a2 -> 'a3 -> 'a4 -> 'a5 -> 'a6 -> 'a7 -> 'a8 -> 'slots Pointer.t
val new10 : ('a0, 'a1, 'a2, 'a3, 'a4, 'a5, 'a6, 'a7, 'a8, 'a9) Slots.t10 as 'slots t -> 'a0 -> 'a1 -> 'a2 -> 'a3 -> 'a4 -> 'a5 -> 'a6 -> 'a7 -> 'a8 -> 'a9 -> 'slots Pointer.t
val new11 : ('a0, 'a1, 'a2, 'a3, 'a4, 'a5, 'a6, 'a7, 'a8, 'a9, 'a10) Slots.t11 as 'slots t -> 'a0 -> 'a1 -> 'a2 -> 'a3 -> 'a4 -> 'a5 -> 'a6 -> 'a7 -> 'a8 -> 'a9 -> 'a10 -> 'slots Pointer.t
val new12 : ('a0, 'a1, 'a2, 'a3, 'a4, 'a5, 'a6, 'a7, 'a8, 'a9, 'a10, 'a11) Slots.t12 as 'slots t -> 'a0 -> 'a1 -> 'a2 -> 'a3 -> 'a4 -> 'a5 -> 'a6 -> 'a7 -> 'a8 -> 'a9 -> 'a10 -> 'a11 -> 'slots Pointer.t
val get_tuple : ('tuple, _) Slots.t as 'slots t -> 'slots Pointer.t -> 'tuple

get_tuple t pointer allocates an OCaml tuple isomorphic to the pool t's tuple pointed to by pointer. The tuple gets copied, but its slots do not.

val get : (_, 'variant) Slots.t as 'slots t -> 'slots Pointer.t -> ('variant, 'slot) Slot.t -> 'slot

get t pointer slot gets slot of the tuple pointed to by pointer in pool t.

set t pointer slot a sets to a the slot of the tuple pointed to by pointer in pool t.

In get and set, it is an error to refer to a pointer that has been freed. It is also an error to use a pointer with any pool other than the one the pointer was new'd from or grown to. These errors will lead to undefined behavior, but will not segfault.

unsafe_get is comparable in speed to get for immediate values, and 5%-10% faster for pointers.

unsafe_get and unsafe_set skip bounds checking, and can thus segfault.

val unsafe_get : (_, 'variant) Slots.t as 'slots t -> 'slots Pointer.t -> ('variant, 'slot) Slot.t -> 'slot
val set : (_, 'variant) Slots.t as 'slots t -> 'slots Pointer.t -> ('variant, 'slot) Slot.t -> 'slot -> Base.Unit.t
val unsafe_set : (_, 'variant) Slots.t as 'slots t -> 'slots Pointer.t -> ('variant, 'slot) Slot.t -> 'slot -> Base.Unit.t
val create : (_, _) Slots.t as 'slots -> capacity:Base.Int.t -> 'slots t

create slots ~capacity creates an empty pool that can hold up to capacity N-tuples. The elements of a free tuple may contain stale and/or invalid values for their types, and as such any access to a free tuple from this pool is unsafe.

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