# Output a pseudo-random number in the interval [0, 1). Example: # # ```elvish-transcript # ~> rand # ▶ 0.17843564133528436 # ``` fn rand { } # Constructs a [typed number](language.html#number). # # If the argument is a string, this command outputs the typed number the # argument represents, or raises an exception if the argument is not a valid # representation of a number. If the argument is already a typed number, this # command outputs it as is. # # This command is usually not needed for working with numbers; see the # discussion of [numeric commands](#numeric-commands). # # Examples: # # ```elvish-transcript # ~> num 10 # ▶ (num 10) # ~> num 0x10 # ▶ (num 16) # ~> num 1/12 # ▶ (num 1/12) # ~> num 3.14 # ▶ (num 3.14) # ~> num (num 10) # ▶ (num 10) # ``` # # See also [`exact-num`]() and [`inexact-num`](). fn num {|string-or-number| } # Coerces the argument to an exact number. If the argument is infinity or NaN, # an exception is thrown. # # If the argument is a string, it is converted to a typed number first. If the # argument is already an exact number, it is returned as is. # # Examples: # # ```elvish-transcript # ~> exact-num (num 0.125) # ▶ (num 1/8) # ~> exact-num 0.125 # ▶ (num 1/8) # ~> exact-num (num 1) # ▶ (num 1) # ``` # # Beware that seemingly simple fractions that can't be represented precisely in # binary can result in the denominator being a very large power of 2: # # ```elvish-transcript # ~> exact-num 0.1 # ▶ (num 3602879701896397/36028797018963968) # ``` # # See also [`num`]() and [`inexact-num`](). fn exact-num {|string-or-number| } # Coerces the argument to an inexact number. # # If the argument is a string, it is converted to a typed number first. If the # argument is already an inexact number, it is returned as is. # # Examples: # # ```elvish-transcript # ~> inexact-num (num 1) # ▶ (num 1.0) # ~> inexact-num (num 0.5) # ▶ (num 0.5) # ~> inexact-num (num 1/2) # ▶ (num 0.5) # ~> inexact-num 1/2 # ▶ (num 0.5) # ``` # # Since the underlying representation for inexact numbers has limited range, # numbers with very large magnitudes may be converted to an infinite value: # # ```elvish-transcript # ~> inexact-num 1000000000000000000 # ▶ (num 1e+18) # ~> inexact-num 10000000000000000000 # ▶ (num +Inf) # ~> inexact-num -10000000000000000000 # ▶ (num -Inf) # ``` # # Likewise, numbers with very small magnitudes may be converted to 0: # # ```elvish-transcript # ~> use math # ~> math:pow 10 -323 # ▶ (num 1/100000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000) # ~> inexact-num (math:pow 10 -323) # ▶ (num 1e-323) # ~> math:pow 10 -324 # ▶ (num 1/1000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000) # ~> inexact-num (math:pow 10 -324) # ▶ (num 0.0) # ``` # # See also [`num`]() and [`exact-num`](). fn inexact-num {|string-or-number| } # Constructs a floating-point number. # # This command is deprecated; use [`num`]() to construct a typed number, or # [`inexact-num`]() to construct an inexact number. fn float64 {|string-or-number| } # ```elvish # < $number... # less # <= $number... # less or equal # == $number... # equal # != $number... # not equal # > $number... # greater # >= $number... # greater or equal # ``` # # Number comparisons. All of them accept an arbitrary number of arguments: # # 1. When given fewer than two arguments, all output `$true`. # # 2. When given two arguments, output whether the two arguments satisfy the named # relationship. # # 3. When given more than two arguments, output whether every adjacent pair of # numbers satisfy the named relationship. # # Examples: # # ```elvish-transcript # ~> == 3 3.0 # ▶ $true # ~> < 3 4 # ▶ $true # ~> < 3 4 10 # ▶ $true # ~> < 6 9 1 # ▶ $false # ``` # # As a consequence of rule 3, the `!=` command outputs `$true` as long as any # _adjacent_ pair of numbers are not equal, even if some numbers that are not # adjacent are equal: # # ```elvish-transcript # ~> != 5 5 4 # ▶ $false # ~> != 5 6 5 # ▶ $true # ``` #doc:id num-cmp #doc:fn < <= == != > >= # Outputs the sum of all arguments, or 0 when there are no arguments. # # This command is [exactness-preserving](#exactness-preserving). # # Examples: # # ```elvish-transcript # ~> + 5 2 7 # ▶ (num 14) # ~> + 1/2 1/3 1/4 # ▶ (num 13/12) # ~> + 1/2 0.5 # ▶ (num 1.0) # ``` #doc:id add fn + {|@num| } # Outputs the result of subtracting from `$x-num` all the `$y-num`s, working # from left to right. When no `$y-num` is given, outputs the negation of # `$x-num` instead (in other words, `- $x-num` is equivalent to `- 0 $x-num`). # # This command is [exactness-preserving](#exactness-preserving). # # Examples: # # ```elvish-transcript # ~> - 5 # ▶ (num -5) # ~> - 5 2 # ▶ (num 3) # ~> - 5 2 7 # ▶ (num -4) # ~> - 1/2 1/3 # ▶ (num 1/6) # ~> - 1/2 0.3 # ▶ (num 0.2) # ~> - 10 # ▶ (num -10) # ``` #doc:id sub fn - {|x-num @y-num| } # Outputs the product of all arguments, or 1 when there are no arguments. # # This command is [exactness-preserving](#exactness-preserving). Additionally, # when any argument is exact 0 and no other argument is a floating-point # infinity, the result is exact 0. # # Examples: # # ```elvish-transcript # ~> * 2 5 7 # ▶ (num 70) # ~> * 1/2 0.5 # ▶ (num 0.25) # ~> * 0 0.5 # ▶ (num 0) # ``` #doc:id mul fn * {|@num| } # Outputs the result of dividing `$x-num` with all the `$y-num`s, working from # left to right. When no `$y-num` is given, outputs the reciprocal of `$x-num` # instead (in other words, `/ $y-num` is equivalent to `/ 1 $y-num`). # # Dividing by exact 0 raises an exception. Dividing by inexact 0 results with # either infinity or NaN according to floating-point semantics. # # This command is [exactness-preserving](#exactness-preserving). Additionally, # when `$x-num` is exact 0 and no `$y-num` is exact 0, the result is exact 0. # # Examples: # # ```elvish-transcript # ~> / 2 # ▶ (num 1/2) # ~> / 2.0 # ▶ (num 0.5) # ~> / 10 5 # ▶ (num 2) # ~> / 2 5 # ▶ (num 2/5) # ~> / 2 5 7 # ▶ (num 2/35) # ~> / 0 1.0 # ▶ (num 0) # ~> / 2 0 # Exception: bad value: divisor must be number other than exact 0, but is exact 0 # [tty 6], line 1: / 2 0 # ~> / 2 0.0 # ▶ (num +Inf) # ``` # # When given no argument, this command is equivalent to `cd /`, due to the # implicit cd feature. (The implicit cd feature will probably change to avoid # this oddity). #doc:id div fn / {|x-num @y-num| } # Outputs the remainder after dividing `$x` by `$y`. The result has the same # sign as `$x`. # # Examples: # # ```elvish-transcript # ~> % 10 3 # ▶ (num 1) # ~> % -10 3 # ▶ (num -1) # ~> % 10 -3 # ▶ (num 1) # ``` # # Note that `%` requires both arguments to be within the range of signed # integers the size of a [machine # word](https://en.wikipedia.org/wiki/Word_(computer_architecture)), and throws # an exception otherwise: # # ```elvish-transcript # ~> % (math:pow 2 63) 3 # Exception: wrong type for arg #0: must be integer # ``` # # This limit may be lifted in the future. #doc:id rem fn % {|x y| } # Output a pseudo-random integer N such that `$low <= N < $high`. If not given, # `$low` defaults to 0. Examples: # # ```elvish-transcript # ~> # Emulate dice # randint 1 7 # ▶ 6 # ``` fn randint {|low? high| } # Sets the seed for the random number generator. #doc:show-unstable fn -randseed {|seed| } # Outputs numbers, starting from `$start` and ending before `$end`, using # `&step` as the increment. # # - If `$start` <= `$end`, `&step` defaults to 1, and `range` outputs values as # long as they are smaller than `$end`. An exception is thrown if `&step` is # given a negative value. # # - If `$start` > `$end`, `&step` defaults to -1, and `range` outputs values as # long as they are greater than `$end`. An exception is thrown if `&step` is # given a positive value. # # As a special case, if the outputs are floating point numbers, `range` also # terminates if the values stop changing. # # This command is [exactness-preserving](#exactness-preserving). # # Examples: # # ```elvish-transcript # ~> range 4 # ▶ (num 0) # ▶ (num 1) # ▶ (num 2) # ▶ (num 3) # ~> range 4 0 # ▶ (num 4) # ▶ (num 3) # ▶ (num 2) # ▶ (num 1) # ~> range -3 3 &step=2 # ▶ (num -3) # ▶ (num -1) # ▶ (num 1) # ~> range 3 -3 &step=-2 # ▶ (num 3) # ▶ (num 1) # ▶ (num -1) # ~> range (- (math:pow 2 53) 1) +inf # ▶ (num 9007199254740991.0) # ▶ (num 9007199254740992.0) # ``` # # When using floating-point numbers, beware that numerical errors can result in # an incorrect number of outputs: # # ```elvish-transcript # ~> range 0.9 &step=0.3 # ▶ (num 0.0) # ▶ (num 0.3) # ▶ (num 0.6) # ▶ (num 0.8999999999999999) # ``` # # Avoid this problem by using exact rationals: # # ```elvish-transcript # ~> range 9/10 &step=3/10 # ▶ (num 0) # ▶ (num 3/10) # ▶ (num 3/5) # ``` # # One usage of this command is to execute something a fixed number of times by # combining with [each](#each): # # ```elvish-transcript # ~> range 3 | each {|_| echo foo } # foo # foo # foo # ``` # # Etymology: # [Python](https://docs.python.org/3/library/functions.html#func-range). fn range {|&step start=0 end| }