The % family of runes is used for making 'function calls' in Hoon. To be more precise, these runes evaluate the $ arm in cores, usually after modifying the sample. (The default sample is replaced with the input values given in the call.)

These runes reduce to the %= rune.

%_ "cencab"

Resolve a wing with changes, preserving type.

Syntax

One fixed argument, then a variable number of pairs.

%_  a=wing
  b=wing  c=hoon
  d=wing  e=hoon
  f=wing  g=hoon
==

%_    a=wing
    b=wing
  c=hoon
::
    d=wing
  e=hoon
::
    f=wing
  g=hoon
==

%_(a=wing b=wing c=hoon, d=wing e=hoon, ...)

AST

[%cncb p=wing q=(list (pair wing hoon))]

Expands to

^+(a %=(a b c, d e, ...))

Semantics

A %_ expression resolves to the value of the subject at wing a, but modified according to a series of changes: b is replaced with the product of c, d with the product of e, and so on. At compile time a type check is performed to ensure that the resulting value is of the same type as a.

Discussion

%_ is different from %= because %= can change the type of a wing with mutations. %_ preserves the wing type.

See how wings are resolved.

Examples

> =foo [p=42 q=6]

> foo(p %baz)
[p=%baz q=6]

> foo(p [55 99])
[p=[55 99] q=6]

> %_(foo p %baz)
[p=7.496.034 99]

> %_(foo p [55 99])
! nest-fail

%: "cencol"

Call a gate with many arguments.

Syntax

One fixed argument, then a variable number of arguments.

%:  a=hoon
  b=hoon
  c=hoon
   ...
  d=hoon
==

%:(a b c d)

  (a b c d)

AST

[%cncl p=hoon q=(list hoon)]

Semantics

A %: expression calls a gate with many arguments. a is the gate to be called, and b through d are the arguments. If there is only one subexpression after a, its product is the sample. Otherwise, a single argument is constructed by evaluating all of b through d -- however many subexpressions there are -- and putting the result in a cell: [b c ... d].

Discussion

When %: is used in tall-form syntax, the series of expressions after p must be terminated with ==.

Examples

> %:  add  22  33  ==
55

> =adder |=  a=*
         =+  c=0
         |-
         ?@  a  (add a c)
         ?^  -.a  !!
         $(c (add -.a c), a +.a)

> %:  adder  22  33  44  ==
99

> %:  adder  22  33  44  55  ==
154

> %:(adder 22 33 44)
99

> (adder 22 33 44)
99

%. "cendot"

Call a gate (function), inverted.

Syntax

Two arguments, fixed.

%.  a  b

%.(a b)

AST

[%cndt p=hoon q=hoon]

Semantics

The %. rune is for evaluating the $ arm of a gate, i.e., calling a function. a is for the desired sample value (i.e., input value), and b is the gate.

Expands to

%-(b=hoon a=hoon)

Discussion

%. is just like %-, but with its subexpressions reversed; the argument comes first, and then the gate.

Examples

> =add-triple |=([a=@ b=@ c=@] :(add a b c))

> %.([1 2 3] add-triple)
6

%- "cenhep"

Call a gate (function).

Syntax

%-  a
b

%-(a b)

  (a b)

AST

[%cnhp p=hoon q=hoon]

Semantics

This rune is for evaluating the $ arm of a gate, i.e., calling a gate as a function. a is the gate, and b is the desired sample value (i.e., input value) for the gate.

Expands to

%~($ a b)

Discussion

%- is used to call a function; a is the function (gate, q the argument. %- is a special case of %~ ("censig"), and a gate is a special case of a door.

Examples

> =add-triple |=([a=@ b=@ c=@] :(add a b c))

> (add-triple 1 2 3)
6

> %-(add-triple [1 2 3])
6

%^ "cenket"

Call gate with triple sample.

Syntax

Four arguments, fixed.

%^    a
    b
  c
d

%^(a b c d)

  (a b c d)

AST

[%cnkt p=hoon q=hoon r=hoon s=hoon]

Expands to

%-(a=hoon [b=hoon c=hoon d=hoon])

Examples

> =add-triple |=([a=@ b=@ c=@] :(add a b c))

> %^(add-triple 1 2 3)
6

%+ "cenlus"

Call gate with a cell sample.

Syntax

Three arguments, fixed.

%+  a
  b
c

%+(a b c)

  (a b c)

AST

[%cnls p=hoon q=hoon r=hoon]

Semantics

A %+ expression is for calling a gate with a cell sample. a is the gate to be called, b is for the head of the sample, and c is for the sample tail.

Expands to

%-(a=hoon [b=hoon c=hoon])

Examples

> =add-triple |=([a=@ b=@ c=@] :(add a b c))

> %+(add-triple 1 [2 3])
6

%~ "censig"

Evaluate an arm in a door.

Syntax

Three arguments, fixed.

%~  p  q
r

%~(p q r)

  ~(p q r1 r2 rn)

In the irregular form, r may be split into multiple parts. Multiple parts of r will be formed into a cell.

Semantics

A %~ expression evaluates the arm of a door (i.e., a core with a sample). a is a wing that resolves to the arm from within the door in question. b is the door itself. c is the sample of the door.

Discussion

%~ is the general case of a function call, %-. In both, we replace the sample (+6) of a core. In %- the core is a gate and the $ arm is evaluated. In %~ the core is a door and any arm may be evaluated. You must identify the arm to be run: %~(arm door arg).

See also |_.

Examples

> =mycore |_  a=@
          ++  plus-two  (add 2 a)
          ++  double  (mul 2 a)
          --

> ~(plus-two mycore 10)
12

> ~(double mycore 10)
20

%* "centar"

Evaluate an expression, then resolve a wing with changes.

Syntax

Two fixed arguments, then a variable number of pairs.

%*  a=wing  b=hoon
  c=wing  d=hoon
  e=wing  f=hoon
       ...
  g=wing  h=hoon
==

%*    a=wing  b=hoon
    c=wing
  d=hoon
::
    e=wing
  f=hoon
::
    g=wing
  h=hoon
==

%*(a b c d, e f, g h)

AST

[%cntr p=wing q=hoon r=(list (pair wing hoon))]

Semantics

A %* expression evaluates some arbitrary Hoon expression, b, and then resolves a wing of that result, with changes. a is the wing to be resolved, and one or more changes is defined by the subexpressions after b.

Expands to

=+  b=hoon
%=  a=wing
  c=wing  d=hoon
  e=wing  f=hoon
       ...
  g=wing  h=hoon
==

Examples

> %*($ add a 2, b 3)
5

> %*(b [a=[12 14] b=[c=12 d=44]] c 11)
[c=11 d=44]

> %*(b [a=[12 14] b=[c=12 d=44]] c 11, d 33)
[c=11 d=33]

> =foo [a=1 b=2 c=3 d=4]

> %*(+ foo c %hello, d %world)
[b=2 c=%hello d=%world]

> =+(foo=[a=1 b=2 c=3] foo(b 7, c 10))
[a=1 b=7 c=10]

> %*(foo [foo=[a=1 b=2 c=3]] b 7, c 10)
[a=1 b=7 c=10]

%= "centis"

Resolve a wing with changes.

Syntax

One fixed argument, then a variable number of pairs.

%=  a=wing
  b=wing  c=hoon
  d=wing  e=hoon
       ...
  f=wing  g=hoon
==

%=    a=wing
    b=wing
  c=hoon
::
    d=wing
  e=hoon
::
    f=wing
  g=hoon
==

%=(a b c, d e, f g)

  a(b c, d e, f g)

AST

[%cnts p=wing q=(list (pair wing hoon))]

Semantics

A %= expression resolves a wing of the subject, but with changes made.

If a resolves to a leg, a series of changes are made to wings of that leg (b, d, and f above are replaced with the respective products of c, e, and g above). The modified leg is returned.

If a resolves to an arm, a series of changes are made to wings of the parent core of that arm. (Again, b, d, and f are replaced with the respective products of c, e, and g.) The arm is computed with the modified core as the subject, and the product is returned.

Discussion

Note that a is a wing, not just any expression. Knowing that a function call (foo baz) involves evaluating foo, replacing its sample at slot +6 with baz, and then resolving to the $ limb, you might think (foo baz) would mean %=(foo +6 baz).

But it's actually =+(foo =>(%=(+2 +6 baz) $)). Even if foo is a wing, we would just be mutating +6 within the core that defines the foo arm. Instead we want to modify the product of foo -- the gate -- so we have to pin it into the subject.

Here's that again in tall form:

=+  foo
=>  %=  +2
      +6  baz
    ==
  $

Examples

> =foo [p=5 q=6]

> foo(p 42)
[p=42 q=6]

> foo(+3 99)
[p=5 99]