ocaml/otherlibs/num/num.mli

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(***********************************************************************)
(* *)
(* Objective Caml *)
(* *)
(* Valerie Menissier-Morain, projet Cristal, INRIA Rocquencourt *)
(* *)
(* Copyright 1996 Institut National de Recherche en Informatique et *)
(* Automatique. Distributed only by permission. *)
(* *)
(***********************************************************************)
(* $Id$ *)
(* Module [Num]: operation on arbitrary-precision numbers *)
open Nat
open Big_int
open Ratio
(* Numbers (type [num]) are arbitrary-precision rational numbers,
plus the special elements [1/0] (infinity) and [0/0] (undefined). *)
type num = Int of int | Big_int of big_int | Ratio of ratio
(* The type of numbers. *)
(* Arithmetic operations *)
val (+/) : num -> num -> num
val add_num : num -> num -> num
(* Addition *)
val minus_num : num -> num
(* Unary negation. *)
val (-/) : num -> num -> num
val sub_num : num -> num -> num
(* Subtraction *)
val ( */ ) : num -> num -> num
val mult_num : num -> num -> num
(* Multiplication *)
val square_num : num -> num
(* Squaring *)
val (//) : num -> num -> num
val div_num : num -> num -> num
(* Division *)
val quo_num : num -> num -> num
val mod_num : num -> num -> num
(* Euclidean division: quotient and remainder *)
val ( **/ ) : num -> num -> num
val power_num : num -> num -> num
(* Exponentiation *)
val is_integer_num : num -> bool
(* Test if a number is an integer *)
val integer_num : num -> num
val floor_num : num -> num
val round_num : num -> num
val ceiling_num : num -> num
(* Approximate a number by an integer.
[floor_num n] returns the largest integer smaller or equal to [n].
[ceiling_num n] returns the smallest integer bigger or equal to [n].
[integer_num n] returns the integer closest to [n]. In case of ties,
rounds towards zero.
[round_num n] returns the integer closest to [n]. In case of ties,
rounds off zero. *)
val sign_num : num -> int
(* Return [-1], [0] or [1] according to the sign of the argument. *)
val (=/) : num -> num -> bool
val (</) : num -> num -> bool
val (>/) : num -> num -> bool
val (<=/) : num -> num -> bool
val (>=/) : num -> num -> bool
val (<>/) : num -> num -> bool
val eq_num : num -> num -> bool
val lt_num : num -> num -> bool
val le_num : num -> num -> bool
val gt_num : num -> num -> bool
val ge_num : num -> num -> bool
(* Usual comparisons between numbers *)
val compare_num : num -> num -> int
(* Return [-1], [0] or [1] if the first argument is less than,
equal to, or greater than the second argument. *)
val max_num : num -> num -> num
val min_num : num -> num -> num
(* Return the greater (resp. the smaller) of the two arguments. *)
val abs_num : num -> num
(* Absolute value. *)
val succ_num: num -> num
(* [succ n] is [n+1] *)
val pred_num: num -> num
(* [pred n] is [n-1] *)
val incr_num: num ref -> unit
(* [incr r] is [r:=!r+1], where [r] is a reference to a number. *)
val decr_num: num ref -> unit
(* [decr r] is [r:=!r-1], where [r] is a reference to a number. *)
(* Coercions with strings *)
val string_of_num : num -> string
(* Convert a number to a string, using fractional notation. *)
val approx_num_fix : int -> num -> string
val approx_num_exp : int -> num -> string
(* Approximate a number by a decimal. The first argument is the
required precision. The second argument is the number to
approximate. [approx_fix] uses decimal notation; the first
argument is the number of digits after the decimal point.
[approx_exp] uses scientific (exponential) notation; the
first argument is the number of digits in the mantissa. *)
val num_of_string : string -> num
(* Convert a string to a number. *)
(* Coercions between numerical types *)
val int_of_num : num -> int
val num_of_int : int -> num
val nat_of_num : num -> nat
val num_of_nat : nat -> num
val num_of_big_int : big_int -> num
val big_int_of_num : num -> big_int
val ratio_of_num : num -> ratio
val num_of_ratio : ratio -> num
val float_of_num : num -> float