63-bit integers.
The size of Int63 is always 63 bits. On a 64-bit platform it is just an int (63-bits), and on a 32-bit platform it is an int64 wrapped to respect the semantic of 63bit integers.
Because Int63 has different representations on 32-bit and 64-bit platforms, marshalling Int63 will not work between 32-bit and 64-bit platforms. unmarshal will segfault.
In 64bit architectures, we expose type t = private int
so that the compiler can
omit caml_modify when dealing with record fields holding Int63.t
.
Code should not explicitly make use of the private
, e.g. via (i :> int)
, since
such code will not compile on 32-bit platforms.
include Base.Int_intf.S with type t = Base__.Int63_backend.t
include Base.Int_intf.S_common
include sig ... end
val hash_fold_t : Base.Hash.state ‑> t ‑> Base.Hash.state
val hash : t ‑> Base.Hash.hash_value
val t_of_sexp : Base.Sexp.t ‑> t
val sexp_of_t : t ‑> Base.Sexp.t
include Base.Identifiable.S with type t := t
include sig ... end
val hash_fold_t : Base.Hash.state ‑> t ‑> Base.Hash.state
val hash : t ‑> Base.Hash.hash_value
val t_of_sexp : Base.Sexp.t ‑> t
val sexp_of_t : t ‑> Base.Sexp.t
include Base.Comparable.S with type t := t
include Base.Comparable_intf.Polymorphic_compare
ascending
is identical to compare
. descending x y = ascending y x
. These are
intended to be mnemonic when used like List.sort ~cmp:ascending
and List.sort
~cmp:descending
, since they cause the list to be sorted in ascending or descending
order, respectively.
clamp_exn t ~min ~max
returns t'
, the closest value to t
such that
between t' ~low:min ~high:max
is true.
Raises if not (min <= max)
.
val clamp : t ‑> min:t ‑> max:t ‑> t Base.Or_error.t
include Base.Comparator.S with type t := t
val comparator : (t, comparator_witness) Base.Comparator.comparator
include Base.Comparable_intf.Validate with type t := t
val validate_lbound : min:t Base.Maybe_bound.t ‑> t Base.Validate.check
val validate_ubound : max:t Base.Maybe_bound.t ‑> t Base.Validate.check
val validate_bound : min:t Base.Maybe_bound.t ‑> max:t Base.Maybe_bound.t ‑> t Base.Validate.check
include Base.Comparable.With_zero with type t := t
val validate_positive : t Base.Validate.check
val validate_non_negative : t Base.Validate.check
val validate_negative : t Base.Validate.check
val validate_non_positive : t Base.Validate.check
val is_positive : t ‑> bool
val is_non_negative : t ‑> bool
val is_negative : t ‑> bool
val is_non_positive : t ‑> bool
val sign : t ‑> Base__.Sign0.t
Returns Neg
, Zero
, or Pos
in a way consistent with the above functions.
val zero : t
val one : t
val minus_one : t
There are two pairs of integer division and remainder functions, /%
and %
, and
/
and rem
. They both satisfy the same equation relating the quotient and the
remainder:
x = (x /% y) * y + (x % y);
x = (x / y) * y + (rem x y);
The functions return the same values if x
and y
are positive. They all raise
if y = 0
.
The functions differ if x < 0
or y < 0
.
If y < 0
, then %
and /%
raise, whereas /
and rem
do not.
x % y
always returns a value between 0 and y - 1
, even when x < 0
. On the
other hand, rem x y
returns a negative value if and only if x < 0
; that value
satisfies abs (rem x y) <= abs y - 1
.
include Base.Int_intf.Round with type t := t
round
rounds an int to a multiple of a given to_multiple_of
argument, according
to a direction dir
, with default dir
being `Nearest
. round
will raise if
to_multiple_of <= 0
.
| `Down | rounds toward Int.neg_infinity | | `Up | rounds toward Int.infinity | | `Nearest | rounds to the nearest multiple, or `Up in case of a tie | | `Zero | rounds toward zero |
Here are some examples for round ~to_multiple_of:10
for each direction:
| `Down | {10 .. 19} --> 10 | { 0 ... 9} --> 0 | {-10 ... -1} --> -10 | | `Up | { 1 .. 10} --> 10 | {-9 ... 0} --> 0 | {-19 .. -10} --> -10 | | `Zero | {10 .. 19} --> 10 | {-9 ... 9} --> 0 | {-19 .. -10} --> -10 | | `Nearest | { 5 .. 14} --> 10 | {-5 ... 4} --> 0 | {-15 ... -6} --> -10 |
For convenience and performance, there are variants of round
with dir
hard-coded.
If you are writing performance-critical code you should use these.
pow base exponent
returns base
raised to the power of exponent
. It is OK if
base <= 0
. pow
raises if exponent < 0
, or an integer overflow would occur.
The results are unspecified for negative shifts and shifts >= num_bits
val decr : t Base__.Import.ref ‑> unit
val incr : t Base__.Import.ref ‑> unit
val of_int32_exn : int32 ‑> t
val to_int32_exn : t ‑> int32
val of_int64_exn : int64 ‑> t
val to_int64 : t ‑> int64
val of_nativeint_exn : nativeint ‑> t
val to_nativeint_exn : t ‑> nativeint
val of_float_unchecked : float ‑> t
of_float_unchecked
truncates the given floating point number to an integer,
rounding towards zero.
The result is unspecified if the argument is nan or falls outside the range
of representable integers.
val num_bits : int
The number of bits available in this integer type. Note that the integer representations are signed
module O : Base.Int_intf.Operators with type t := t
A sub-module designed to be opened to make working with ints more convenient.
module Overflow_exn : sig ... end
Unlike the usual operations, these never overflow, preferring instead to raise.
val of_int : int ‑> t
val to_int : t ‑> int option
val of_int32 : Base.Int32.t ‑> t
val random : ?state:Base.Random.State.t ‑> t ‑> t
random ~state bound
returns a random integer between 0 (inclusive) and bound
(exclusive). bound
must be greater than 0.
The default ~state
is Random.State.default
.
val random_incl : ?state:Base.Random.State.t ‑> t ‑> t ‑> t
random_incl ~state lo hi
returns a random integer between lo
(inclusive) and hi
(inclusive). Raises if lo > hi
.
The default ~state
is Random.State.default
.