Int64

Utility functions on 64-bit signed integers.

Note that most operations are available as built-in operators (e.g. 1 + 1).

Import from the core package to use this module.

motoko name=import
import Int64 "mo:core/Int64";

type Int64 = Prim.Types.Int64

64-bit signed integers.

public let minValue : Int64

Minimum 64-bit integer value, -2 ** 63.

Example:

motoko include=import
assert Int64.minValue == -9_223_372_036_854_775_808;

public let maxValue : Int64

Maximum 64-bit integer value, +2 ** 63 - 1.

Example:

motoko include=import
assert Int64.maxValue == +9_223_372_036_854_775_807;

public func toInt(self : Int64) : Int

Converts a 64-bit signed integer to a signed integer with infinite precision.

Example:

motoko include=import
assert Int64.toInt(123_456) == (123_456 : Int);

public func fromInt(_ : Int) : Int64

Converts a signed integer with infinite precision to a 64-bit signed integer.

Traps on overflow/underflow.

Example:

motoko include=import
assert Int64.fromInt(123_456) == (+123_456 : Int64);

public func fromInt32(_ : Int32) : Int64

Converts a 32-bit signed integer to a 64-bit signed integer.

Traps on overflow/underflow.

Example:

motoko include=import
assert Int64.fromInt32(-123_456) == (-123_456 : Int64);

public func toInt32(self : Int64) : Int32

Converts a 64-bit signed integer to a 32-bit signed integer.

Wraps on overflow/underflow.

Example:

motoko include=import
assert Int64.toInt32(-123_456) == (-123_456 : Int32);

public func fromIntWrap(_ : Int) : Int64

Converts a signed integer with infinite precision to a 64-bit signed integer.

Wraps on overflow/underflow.

Example:

motoko include=import
assert Int64.fromIntWrap(-123_456) == (-123_456 : Int64);

public func fromNat64(_ : Nat64) : Int64

Converts an unsigned 64-bit integer to a signed 64-bit integer.

Wraps on overflow/underflow.

Example:

motoko include=import
assert Int64.fromNat64(123_456) == (+123_456 : Int64);

public func toNat64(self : Int64) : Nat64

Converts a signed 64-bit integer to an unsigned 64-bit integer.

Wraps on overflow/underflow.

Example:

motoko include=import
assert Int64.toNat64(-1) == (18_446_744_073_709_551_615 : Nat64); // underflow

public func toText(self : Int64) : Text

Returns the Text representation of x. Textual representation do not contain underscores to represent commas.

Example:

motoko include=import
assert Int64.toText(-123456) == "-123456";

public func abs(x : Int64) : Int64

Returns the absolute value of x.

Traps when x == -2 ** 63 (the minimum Int64 value).

Example:

motoko include=import
assert Int64.abs(-123456) == +123_456;

public func min(x : Int64, y : Int64) : Int64

Returns the minimum of x and y.

Example:

motoko include=import
assert Int64.min(+2, -3) == -3;

public func max(x : Int64, y : Int64) : Int64

Returns the maximum of x and y.

Example:

motoko include=import
assert Int64.max(+2, -3) == +2;

public func equal(x : Int64, y : Int64) : Bool

Equality function for Int64 types. This is equivalent to x == y.

Example:

motoko include=import
assert Int64.equal(-1, -1);

Note: The reason why this function is defined in this library (in addition to the existing == operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use == as a function value at the moment.

Example:

motoko include=import
let a : Int64 = -123;
let b : Int64 = 123;
assert not Int64.equal(a, b);

public func notEqual(x : Int64, y : Int64) : Bool

Inequality function for Int64 types. This is equivalent to x != y.

Example:

motoko include=import
assert Int64.notEqual(-1, -2);

Note: The reason why this function is defined in this library (in addition to the existing != operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use != as a function value at the moment.

public func less(x : Int64, y : Int64) : Bool

"Less than" function for Int64 types. This is equivalent to x < y.

Example:

motoko include=import
assert Int64.less(-2, 1);

Note: The reason why this function is defined in this library (in addition to the existing < operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use < as a function value at the moment.

public func lessOrEqual(x : Int64, y : Int64) : Bool

"Less than or equal" function for Int64 types. This is equivalent to x <= y.

Example:

motoko include=import
assert Int64.lessOrEqual(-2, -2);

Note: The reason why this function is defined in this library (in addition to the existing <= operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use <= as a function value at the moment.

public func greater(x : Int64, y : Int64) : Bool

"Greater than" function for Int64 types. This is equivalent to x > y.

Example:

motoko include=import
assert Int64.greater(-2, -3);

Note: The reason why this function is defined in this library (in addition to the existing > operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use > as a function value at the moment.

public func greaterOrEqual(x : Int64, y : Int64) : Bool

"Greater than or equal" function for Int64 types. This is equivalent to x >= y.

Example:

motoko include=import
assert Int64.greaterOrEqual(-2, -2);

Note: The reason why this function is defined in this library (in addition to the existing >= operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use >= as a function value at the moment.

public func compare(x : Int64, y : Int64) : Order.Order

General-purpose comparison function for Int64. Returns the Order ( either #less, #equal, or #greater) of comparing x with y.

Example:

motoko include=import
assert Int64.compare(-3, 2) == #less;

This function can be used as value for a high order function, such as a sort function.

Example:

motoko include=import
import Array "mo:core/Array";
assert Array.sort([1, -2, -3] : [Int64], Int64.compare) == [-3, -2, 1];

public func neg(x : Int64) : Int64

Returns the negation of x, -x.

Traps on overflow, i.e. for neg(-2 ** 63).

Example:

motoko include=import
assert Int64.neg(123) == -123;

Note: The reason why this function is defined in this library (in addition to the existing - operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use - as a function value at the moment.

public func add(x : Int64, y : Int64) : Int64

Returns the sum of x and y, x + y.

Traps on overflow/underflow.

Example:

motoko include=import
assert Int64.add(1234, 123) == +1_357;

Note: The reason why this function is defined in this library (in addition to the existing + operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use + as a function value at the moment.

Example:

motoko include=import
import Array "mo:core/Array";
assert Array.foldLeft<Int64, Int64>([1, -2, -3], 0, Int64.add) == -4;

public func sub(x : Int64, y : Int64) : Int64

Returns the difference of x and y, x - y.

Traps on overflow/underflow.

Example:

motoko include=import
assert Int64.sub(123, 100) == +23;

Note: The reason why this function is defined in this library (in addition to the existing - operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use - as a function value at the moment.

Example:

motoko include=import
import Array "mo:core/Array";
assert Array.foldLeft<Int64, Int64>([1, -2, -3], 0, Int64.sub) == 4;

public func mul(x : Int64, y : Int64) : Int64

Returns the product of x and y, x * y.

Traps on overflow/underflow.

Example:

motoko include=import
assert Int64.mul(123, 10) == +1_230;

Note: The reason why this function is defined in this library (in addition to the existing * operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use * as a function value at the moment.

Example:

motoko include=import
import Array "mo:core/Array";
assert Array.foldLeft<Int64, Int64>([1, -2, -3], 1, Int64.mul) == 6;

public func div(x : Int64, y : Int64) : Int64

Returns the signed integer division of x by y, x / y. Rounds the quotient towards zero, which is the same as truncating the decimal places of the quotient.

Traps when y is zero.

Example:

motoko include=import
assert Int64.div(123, 10) == +12;

Note: The reason why this function is defined in this library (in addition to the existing / operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use / as a function value at the moment.

public func rem(x : Int64, y : Int64) : Int64

Returns the remainder of the signed integer division of x by y, x % y, which is defined as x - x / y * y.

Traps when y is zero.

Example:

motoko include=import
assert Int64.rem(123, 10) == +3;

Note: The reason why this function is defined in this library (in addition to the existing % operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use % as a function value at the moment.

public func pow(x : Int64, y : Int64) : Int64

Returns x to the power of y, x ** y.

Traps on overflow/underflow and when y < 0 or y >= 64.

Example:

motoko include=import
assert Int64.pow(2, 10) == +1_024;

Note: The reason why this function is defined in this library (in addition to the existing ** operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use ** as a function value at the moment.

public func bitnot(x : Int64) : Int64

Returns the bitwise negation of x, ^x.

Example:

motoko include=import
assert Int64.bitnot(-256 /* 0xffff_ffff_ffff_ff00 */) == +255 // 0xff;

Note: The reason why this function is defined in this library (in addition to the existing ^ operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use ^ as a function value at the moment.

public func bitand(x : Int64, y : Int64) : Int64

Returns the bitwise "and" of x and y, x & y.

Example:

motoko include=import
assert Int64.bitand(0xffff, 0x00f0) == +240 // 0xf0;

Note: The reason why this function is defined in this library (in addition to the existing & operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use & as a function value at the moment.

public func bitor(x : Int64, y : Int64) : Int64

Returns the bitwise "or" of x and y, x | y.

Example:

motoko include=import
assert Int64.bitor(0xffff, 0x00f0) == +65_535 // 0xffff;

Note: The reason why this function is defined in this library (in addition to the existing | operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use | as a function value at the moment.

public func bitxor(x : Int64, y : Int64) : Int64

Returns the bitwise "exclusive or" of x and y, x ^ y.

Example:

motoko include=import
assert Int64.bitxor(0xffff, 0x00f0) == +65_295 // 0xff0f;

Note: The reason why this function is defined in this library (in addition to the existing ^ operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use ^ as a function value at the moment.

public func bitshiftLeft(x : Int64, y : Int64) : Int64

Returns the bitwise left shift of x by y, x << y. The right bits of the shift filled with zeros. Left-overflowing bits, including the sign bit, are discarded.

For y >= 64, the semantics is the same as for bitshiftLeft(x, y % 64). For y < 0, the semantics is the same as for bitshiftLeft(x, y + y % 64).

Example:

motoko include=import
assert Int64.bitshiftLeft(1, 8) == +256 // 0x100 equivalent to `2 ** 8`.;

Note: The reason why this function is defined in this library (in addition to the existing << operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use << as a function value at the moment.

public func bitshiftRight(x : Int64, y : Int64) : Int64

Returns the signed bitwise right shift of x by y, x >> y. The sign bit is retained and the left side is filled with the sign bit. Right-underflowing bits are discarded, i.e. not rotated to the left side.

For y >= 64, the semantics is the same as for bitshiftRight(x, y % 64). For y < 0, the semantics is the same as for bitshiftRight (x, y + y % 64).

Example:

motoko include=import
assert Int64.bitshiftRight(1024, 8) == +4 // equivalent to `1024 / (2 ** 8)`;

Note: The reason why this function is defined in this library (in addition to the existing >> operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use >> as a function value at the moment.

public func bitrotLeft(x : Int64, y : Int64) : Int64

Returns the bitwise left rotatation of x by y, x <<> y. Each left-overflowing bit is inserted again on the right side. The sign bit is rotated like y bits, i.e. the rotation interprets the number as unsigned.

Changes the direction of rotation for negative y. For y >= 64, the semantics is the same as for bitrotLeft(x, y % 64).

Example:

motoko include=import

assert Int64.bitrotLeft(0x2000_0000_0000_0001, 4) == +18 // 0x12.;

Note: The reason why this function is defined in this library (in addition to the existing <<> operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use <<> as a function value at the moment.

public func bitrotRight(x : Int64, y : Int64) : Int64

Returns the bitwise right rotation of x by y, x <>> y. Each right-underflowing bit is inserted again on the right side. The sign bit is rotated like y bits, i.e. the rotation interprets the number as unsigned.

Changes the direction of rotation for negative y. For y >= 64, the semantics is the same as for bitrotRight(x, y % 64).

Example:

motoko include=import
assert Int64.bitrotRight(0x0002_0000_0000_0001, 48) == +65538 // 0x1_0002.;

Note: The reason why this function is defined in this library (in addition to the existing <>> operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use <>> as a function value at the moment.

public func bittest(x : Int64, p : Nat) : Bool

Returns the value of bit p in x, x & 2**p == 2**p. If p >= 64, the semantics is the same as for bittest(x, p % 64). This is equivalent to checking if the p-th bit is set in x, using 0 indexing.

Example:

motoko include=import
assert Int64.bittest(128, 7);

public func bitset(x : Int64, p : Nat) : Int64

Returns the value of setting bit p in x to 1. If p >= 64, the semantics is the same as for bitset(x, p % 64).

Example:

motoko include=import
assert Int64.bitset(0, 7) == +128;

public func bitclear(x : Int64, p : Nat) : Int64

Returns the value of clearing bit p in x to 0. If p >= 64, the semantics is the same as for bitclear(x, p % 64).

Example:

motoko include=import
assert Int64.bitclear(-1, 7) == -129;

public func bitflip(x : Int64, p : Nat) : Int64

Returns the value of flipping bit p in x. If p >= 64, the semantics is the same as for bitclear(x, p % 64).

Example:

motoko include=import
assert Int64.bitflip(255, 7) == +127;

public func bitcountNonZero(x : Int64) : Int64

Returns the count of non-zero bits in x.

Example:

motoko include=import
assert Int64.bitcountNonZero(0xffff) == +16;

public func bitcountLeadingZero(x : Int64) : Int64

Returns the count of leading zero bits in x.

Example:

motoko include=import
assert Int64.bitcountLeadingZero(0x8000_0000) == +32;

public func bitcountTrailingZero(x : Int64) : Int64

Returns the count of trailing zero bits in x.

Example:

motoko include=import
assert Int64.bitcountTrailingZero(0x0201_0000) == +16;

public func explode(x : Int64) : (msb : Nat8, Nat8, Nat8, Nat8, Nat8, Nat8, Nat8, lsb : Nat8)

Returns the upper (i.e. most significant), lower (least significant) and in-between bytes of x.

Example:

motoko include=import
assert Int64.explode 0x33772266aa885511 == (51, 119, 34, 102, 170, 136, 85, 17);

public func addWrap(x : Int64, y : Int64) : Int64

Returns the sum of x and y, x +% y.

Wraps on overflow/underflow.

Example:

motoko include=import
assert Int64.addWrap(2 ** 62, 2 ** 62) == -9_223_372_036_854_775_808; // overflow

Note: The reason why this function is defined in this library (in addition to the existing +% operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use +% as a function value at the moment.

public func subWrap(x : Int64, y : Int64) : Int64

Returns the difference of x and y, x -% y.

Wraps on overflow/underflow.

Example:

motoko include=import
assert Int64.subWrap(-2 ** 63, 1) == +9_223_372_036_854_775_807; // underflow

Note: The reason why this function is defined in this library (in addition to the existing -% operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use -% as a function value at the moment.

public func mulWrap(x : Int64, y : Int64) : Int64

Returns the product of x and y, x *% y. Wraps on overflow.

Wraps on overflow/underflow.

Example:

motoko include=import
assert Int64.mulWrap(2 ** 32, 2 ** 32) == 0; // overflow

Note: The reason why this function is defined in this library (in addition to the existing *% operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use *% as a function value at the moment.

public func powWrap(x : Int64, y : Int64) : Int64

Returns x to the power of y, x **% y.

Wraps on overflow/underflow. Traps if y < 0 or y >= 64.

Example:

motoko include=import
assert Int64.powWrap(2, 63) == -9_223_372_036_854_775_808; // overflow

Note: The reason why this function is defined in this library (in addition to the existing **% operator) is so that you can use it as a function value to pass to a higher order function. It is not possible to use **% as a function value at the moment.

public func range(fromInclusive : Int64, toExclusive : Int64) : Iter.Iter<Int64>

Returns an iterator over Int64 values from the first to second argument with an exclusive upper bound.

motoko include=import
import Iter "mo:core/Iter";

let iter = Int64.range(1, 4);
assert iter.next() == ?1;
assert iter.next() == ?2;
assert iter.next() == ?3;
assert iter.next() == null;

If the first argument is greater than the second argument, the function returns an empty iterator.

motoko include=import
import Iter "mo:core/Iter";

let iter = Int64.range(4, 1);
assert iter.next() == null; // empty iterator

public func rangeInclusive(from : Int64, to : Int64) : Iter.Iter<Int64>

Returns an iterator over Int64 values from the first to second argument, inclusive.

motoko include=import
import Iter "mo:core/Iter";

let iter = Int64.rangeInclusive(1, 3);
assert iter.next() == ?1;
assert iter.next() == ?2;
assert iter.next() == ?3;
assert iter.next() == null;

If the first argument is greater than the second argument, the function returns an empty iterator.

motoko include=import
import Iter "mo:core/Iter";

let iter = Int64.rangeInclusive(4, 1);
assert iter.next() == null; // empty iterator

public func allValues() : Iter.Iter<Int64>

Returns an iterator over all Int64 values, from minValue to maxValue.

motoko include=import
import Iter "mo:core/Iter";

let iter = Int64.allValues();
assert iter.next() == ?-9_223_372_036_854_775_808;
assert iter.next() == ?-9_223_372_036_854_775_807;
assert iter.next() == ?-9_223_372_036_854_775_806;
// ...