++by
Map operations
Container arm for map operation arms. A map is a set of key-value pairs. The contained arms inherit its sample map, a
.
Accepts
a
is a map.
Source
++ by~/ %by=| a=(tree (pair)) :: (map)=* node ?>(?=(^ a) n.a)|@
Examples
> ~(. by (malt (limo ~[a+1 b+2 c+3])))< 27.jus[ a?(%~[ n=[?(p=%a p=%b p=%c) q=@ud]l=nlr([p=?(%a %b %c) q=@ud])r=nlr([p=?(%a %b %c) q=@ud])])<123.zao 46.hgz 1.pnw %140>]>
++all:by
Logical AND
Computes the logical AND on the results of slamming every element in map a
with gate b
.
Accepts
a
is a map, and is the sample of +by
.
b
is a gate.
Produces
A flag.
Source
++ all~/ %all|* b=$-(* ?)|- ^- ??~ a&?&((b q.n.a) $(a l.a) $(a r.a))
Examples
> =a (malt (limo ~[a+1 b+[2 3]]))> (~(all by a) |=(a=* ?@(a & |)))%.n
> =a (malt (limo ~[a+1 b+2 c+3 d+4 e+5]))> (~(all by a) |=(a=@ (lte a 6)))%.y> (~(all by a) |=(a=@ (lte a 4)))%.n
++any:by
Logical OR
Computes the logical OR on the results of slamming every element with gate b
.
Accepts
a
is a map, and is the sample of +by
.
b
is a wet gate.
Produces
A flag.
Source
++ any~/ %any|* b=$-(* ?)|- ^- ??~ a|?|((b q.n.a) $(a l.a) $(a r.a))
Examples
> =a (malt (limo ~[a+1 b+[2 3]]))> (~(any by a) |=(a=* ?@(a & |)))%.y
> =a (malt (limo ~[a+1 b+2 c+3 d+4 e+5]))> (~(any by a) |=(a=@ (lte a 4)))%.y
++apt:by
Check correctness
Computes whether a
has a correct horizontal order and a correct vertical order, producing a flag.
Accepts
a
is a map.
Produces
A flag.
Source
++ apt=< $~/ %apt=| [l=(unit) r=(unit)]|. ^- ??~ a &?& ?~(l & &((gor p.n.a u.l) !=(p.n.a u.l)))?~(r & &((gor u.r p.n.a) !=(u.r p.n.a)))?~ l.a &&((mor p.n.a p.n.l.a) !=(p.n.a p.n.l.a) $(a l.a, l `p.n.a))?~ r.a &&((mor p.n.a p.n.r.a) !=(p.n.a p.n.r.a) $(a r.a, r `p.n.a))==
Examples
> =a (malt `(list [@tas @])`~[a+1 b+2 c+3 d+4 e+5])> ~(apt by a)%.y> =z ?~(a ~ a(p.n `@tas`%z))> z[n=[p=%z q=2] l={[p=%e q=5]} r={[p=%d q=4] [p=%a q=1] [p=%c q=3]}]> ~(apt by z)%.n
Discussion
See section 2f
for more information on noun ordering.
++bif:by
Bifurcate
Splits map a
into two maps l
and r
, which contain the items either side of key b
with value c
but not including b
-c
.
Accepts
a
is a map, and is the sample of +by
.
b
is a noun.
c
is a noun.
Produces
A cell of two maps.
Source
++ bif~/ %bif|* [b=* c=*]^+ [l=a r=a]=< +|- ^+ a?~ a[[b c] ~ ~]?: =(b p.n.a)?: =(c q.n.a)aa(n [b c])?: (gor b p.n.a)=+ d=$(a l.a)?> ?=(^ d)d(r a(l r.d))=+ d=$(a r.a)?> ?=(^ d)d(l a(r l.d))
Examples
> =a (malt `(list [@tas @])`~[a+1 b+2 c+3 d+4 e+5])> (~(bif by a) b+2)[l=[n=[p=%e q=5] l=~ r=~] r=[n=[p=%d q=4] l=~ r=[n=[p=%c q=3] l={[p=%a q=1]} r={}]]]> `[(map @tas @) (map @tas @)]`(~(bif by a) b+2)[{[p=%e q=5]} {[p=%d q=4] [p=%a q=1] [p=%c q=3]}]
Discussion
Note that map
s are horizontally ordered by the mug hash of their keys and vertically ordered by the double-mug
hash of their keys. This means bifurcating the map (malt ~[10^10 20^20 30^30 40^40 50^50])
at 30^30
will not produce [{10^10 20^20} {40^40 50^50}]
, but rather [{20^20} {10^10 40^40 50^50}]
due to the tree structure resulting from their mug
hashes.
++del:by
Delete
Produces map a
with the element located at key b
removed.
Accepts
a
is a map, and is the sample of +by
.
b
is a key as a noun.
Produces
A map.
Source
++ del~/ %del|* b=*|- ^+ a?~ a~?. =(b p.n.a)?: (gor b p.n.a)a(l $(a l.a))a(r $(a r.a))|- ^- [$?(~ _a)]?~ l.a r.a?~ r.a l.a?: (mor p.n.l.a p.n.r.a)l.a(r $(l.a r.l.a))r.a(l $(r.a l.r.a))
Examples
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3 d+4]))> a{[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> `(map @tas @)`(~(del by a) %z){[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> `(map @tas @)`(~(del by a) %b){[p=%d q=4] [p=%a q=1] [p=%c q=3]}
++dif:by
Difference
Computes the difference between a
and b
, producing the map of key-value pairs in a
whose keys are not in b
.
Accepts
a
is a map
, and is the sample of +by
.
b
is a map
.
Produces
A map
.
Source
++ dif~/ %dif=+ b=a|@++ $|- ^+ a?~ ba=+ c=(bif p.n.b q.n.b)?> ?=(^ c)=+ d=$(a l.c, b l.b)=+ e=$(a r.c, b r.b)|- ^- [$?(~ _a)]?~ d e?~ e d?: (mor p.n.d p.n.e)d(r $(d r.d))e(l $(e l.e))--
Examples
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3 d+4]))> =b `(map @tas @)`(malt (limo ~[c+3 d+4 e+5 f+6]))> a{[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> b{[p=%e q=5] [p=%d q=4] [p=%f q=6] [p=%c q=3]}> `(map @tas @)`(~(dif by a) b){[p=%b q=2] [p=%a q=1]}
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3 d+4]))> =b `(map @tas @)`(malt (limo ~[a+2 e+4 f+5]))> a{[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> b{[p=%e q=4] [p=%f q=5] [p=%a q=2]}> `(map @tas @)`(~(dif by a) b){[p=%b q=2] [p=%d q=4] [p=%c q=3]}
Discussion
This only compares keys, so if both maps contain the same key with different values, that key-value pair is not considered a difference and will not be included in the resulting map.
++dig:by
Address of key
Produce the address of key b
within map a
.
Accepts
a
is a map, and is the sample of +by
.
b
is a key as a noun.
Produces
A unit.
Source
++ dig|= b=*=+ c=1|- ^- (unit @)?~ a ~?: =(b p.n.a) [~ u=(peg c 2)]?: (gor b p.n.a)$(a l.a, c (peg c 6))$(a r.a, c (peg c 7))
Examples
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3 d+4]))> (~(dig by a) %a)[~ 252]> (~(dig by a) %b)[~ 2]> (~(dig by a) %e)~
++gas:by
Concatenate
Insert a list of key-value pairs b
into map a
. For a key which exists in both a
and b
, the value is replaced with the value in b
.
Accepts
a
is a map, and is the sample of +by
.
b
is a list of cells of key-value nouns p
and q
.
Produces
A map.
Source
++ gas~/ %gas|* b=(list [p=* q=*])=> .(b `(list _?>(?=(^ a) n.a))`b)|- ^+ a?~ ba$(b t.b, a (put p.i.b q.i.b))
Examples
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3 d+4]))> a{[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> `(map @tas @)`(~(gas by a) ~[e+5 f+6 g+7]){[p=%e q=5] [p=%b q=2] [p=%d q=4] [p=%f q=6] [p=%g q=7] [p=%a q=1] [p=%c q=3]}
> =a `(map @tas @)`(malt (limo ~[a+1 b+2]))> a{[p=%b q=2] [p=%a q=1]}> `(map @tas @)`(~(gas by a) ~[a+100 b+200]){[p=%b q=200] [p=%a q=100]}
> `(map @tas @)`(~(gas by `(map @tas @)`~) ~[a+100 b+200]){[p=%b q=200] [p=%a q=100]}
++get:by
Grab unit value
Produce the unit value of the value located at key b
within map a
.
Accepts
a
is a map, and is the sample of +by
.
b
is a key as a noun.
Produces
A unit.
Source
++ get~/ %get|* b=*=> .(b `_?>(?=(^ a) p.n.a)`b)|- ^- (unit _?>(?=(^ a) q.n.a))?~ a~?: =(b p.n.a)(some q.n.a)?: (gor b p.n.a)$(a l.a)$(a r.a)
Examples
> a{[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> (~(get by a) %a)[~ 1]> (~(get by a) %b)[~ 2]> (~(get by a) %z)~
++got:by
Assert
Produce the value located at key b
within map a
. Crash if key b
does not exist.
Accepts
a
is a map, and is the sample of +by
.
b
is a key as a noun.
Produces
A noun.
Source
++ got|* b=*(need (get b))
Examples
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3 d+4]))> a{[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> (~(got by a) %a)1> (~(got by a) %b)2> (~(got by a) %z)dojo: hoon expression failed
++gut:by
Grab value with default
Produce the value located at key b
within map a
. Use default value c
if key does not exist.
Accepts
a
is a map, and is the sample of +by
.
b
is a key as a noun.
c
is a noun.
Produces
A noun.
Source
++ gut|* [b=* c=*](fall (get b) c)
Examples
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3 d+4]))> a{[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> (~(gut by a) %a 9.999)1> (~(gut by a) %b 9.999)2> (~(gut by a) %z 9.999)9.999
++has:by
Key existence check
Checks whether map a
contains an element with key b
, producing a flag.
Accepts
a
is a map, and is the sample of +by
.
b
is a key as a noun.
Produces
A flag.
Source
++ has~/ %has|* b=*!=(~ (get b))
Examples
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3 d+4]))> a{[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> (~(has by a) %a)%.y> (~(has by a) %z)%.n
++int:by
Intersection
Produces a map of the (key) intersection between two maps of the same type, a
and b
. If both maps have an identical key that point to different values, the element from map b
is used.
Accepts
a
is a map, and is the sample of +by
.
b
is a map.
Produces
A map.
Source
++ int~/ %int=+ b=a|@++ $|- ^+ a?~ b~?~ a~?: (mor p.n.a p.n.b)?: =(p.n.b p.n.a)b(l $(a l.a, b l.b), r $(a r.a, b r.b))?: (gor p.n.b p.n.a)%- uni(a $(a l.a, r.b ~)) $(b r.b)%- uni(a $(a r.a, l.b ~)) $(b l.b)?: =(p.n.a p.n.b)b(l $(b l.b, a l.a), r $(b r.b, a r.a))?: (gor p.n.a p.n.b)%- uni(a $(b l.b, r.a ~)) $(a r.a)%- uni(a $(b r.b, l.a ~)) $(a l.a)--
Examples
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3 d+4]))> =b `(map @tas @)`(malt (limo ~[c+3 d+4 e+5 f+6]))> a{[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> b{[p=%e q=5] [p=%d q=4] [p=%f q=6] [p=%c q=3]}> `(map @tas @)`(~(int by a) b){[p=%d q=4] [p=%c q=3]}
> =a `(map @tas @)`(malt (limo ~[a+1 b+2]))> =b `(map @tas @)`(malt (limo ~[a+100 b+200]))> a{[p=%b q=2] [p=%a q=1]}> b{[p=%b q=200] [p=%a q=100]}> `(map @tas @)`(~(int by a) b){[p=%b q=200] [p=%a q=100]}
++jab:by
Transform value
Produce map a
with the value at key b
transformed by gate c
.
Accepts
a
is a map
, and is the sample of +by
.
b
is a noun, and a key in a
.
c
is a gate
.
Produces
A map
.
Source
++ jab~/ %jab|* [key=_?>(?=(^ a) p.n.a) fun=$-(_?>(?=(^ a) q.n.a) _?>(?=(^ a) q.n.a))]^+ a::?~ a !!::?: =(key p.n.a)a(q.n (fun q.n.a))::?: (gor key p.n.a)a(l $(a l.a))::a(r $(a r.a))
Examples
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3 d+4]))> a{[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> `(map @tas @)`(~(jab by a) %d |=(x=@ (pow x 2))){[p=%b q=2] [p=%d q=16] [p=%a q=1] [p=%c q=3]}> (~(jab by a) %z |=(x=@ (pow x 2)))dojo: hoon expression failed> (~(jab by a) %d |=(a=@ [a a]))-need.?(%~ [n=[p=@tas q=@] l=nlr([p=@tas q=@]) r=nlr([p=@tas q=@])])-have.[n=[p=@tas q=[@ @]] l=nlr([p=@tas q=@]) r=nlr([p=@tas q=@])]nest-faildojo: hoon expression failed
++key:by
Set of keys
Produces a set of all keys in map a
.
Accepts
a
is a map, and is the sample of +by
.
Produces
A set.
Source
++ key=< $~/ %key=+ b=`(set _?>(?=(^ a) p.n.a))`~|. ^+ b?~ a b$(a r.a, b $(a l.a, b (~(put in b) p.n.a)))
Examples
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3 d+4]))> ~(key by a){%b %d %a %c}
++mar:by
Add with validation
Produces map a
with the addition of key-value pair b
and c
, where the value is a nonempty unit.
Accept a noun and a unit of a noun of the type of the map's keys and values, respectively. Validate that the value is not null and put the pair in the map. If the value is null, delete the key.
Accepts
a
is a map
, and is the sample of +by
.
b
is a noun.
c
is a unit
.
Produces
A map.
Source
++ mar|* [b=* c=(unit *)]?~ c(del b)(put b u.c)
Examples
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3 d+4]))> a{[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> `(map @tas @)`(~(mar by a) %e (some 5)){[p=%e q=5] [p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> `(map @tas @)`(~(mar by a) %a (some 10)){[p=%b q=2] [p=%d q=4] [p=%a q=10] [p=%c q=3]}> `(map @tas @)`(~(mar by a) %a ~){[p=%b q=2] [p=%d q=4] [p=%c q=3]}
++put:by
Add key-value pair
Produces a
with the addition of the key-value pair of b
and c
.
Accepts
a
is a map, and is the sample of +by
.
b
is a key of the same type as the keys in a
.
c
is a value of the same type of the values in a
.
Produces
A map.
Source
++ put~/ %put|* [b=* c=*]|- ^+ a?~ a[[b c] ~ ~]?: =(b p.n.a)?: =(c q.n.a)aa(n [b c])?: (gor b p.n.a)=+ d=$(a l.a)?> ?=(^ d)?: (mor p.n.a p.n.d)a(l d)d(r a(l r.d))=+ d=$(a r.a)?> ?=(^ d)?: (mor p.n.a p.n.d)a(r d)d(l a(r l.d))
Examples
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3]))> a{[p=%b q=2] [p=%a q=1] [p=%c q=3]}> `(map @tas @)`(~(put by a) %d 4){[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> `(map @tas @)`(~(put by a) %a 10){[p=%b q=2] [p=%a q=10] [p=%c q=3]}> (~(put by a) 42 'foo')mull-growmull-nice-need.?(%~ [n=[p=@tas q=@] l=nlr([p=@tas q=@]) r=nlr([p=@tas q=@])])-have.[[@ud @t] %~ %~]nest-faildojo: hoon expression failed
++rep:by
Reduce to product
Accumulate elements of map a
using gate b
, producing a noun.
Accepts
a
is a map.
b
is a gate.
Produces
A noun.
Source
++ rep~/ %rep|* b=_=>(~ |=([* *] +<+))|-?~ a +<+.b$(a r.a, +<+.b $(a l.a, +<+.b (b n.a +<+.b)))
Examples
> =a `(map @tas @)`(malt (limo ~[a+1 b+2 c+3 d+4]))> a{[p=%b q=2] [p=%d q=4] [p=%a q=1] [p=%c q=3]}> (~(rep by a) |=([p=[@tas @] q=@] ~&([p q] (add +.p q))))[[%b 2] 0][[%d 4] 2][[%c 3] 6][[%a 1] 9]q=10
Discussion
The gate will iteratively be fed a cell whose head is a key-value pair from the map and whose tail is an accumulator, producing the final value of the accumulator.
++rib:by
Transform + product
c
is a gate with a sample like [[key value] accumulator]
and a product like [accumulator [key value]]
. Each key-value pair in map a
is passed to c
and replaced with the key-value pair c
produced. The final value of the accumulator and the modified map are returned. b
is the initial value of the accumulator.
Accepts
a
is a map, and is the sample of +by
.
b
is a noun, and is the initial value of the accumulator.
c
is a gate.
Produces
A cell of a noun and a map.
Source
++ rib|* [b=* c=gate]|- ^+ [b a]?~ a [b ~]=+ d=(c n.a b)=. n.a +.d=+ e=$(a l.a, b -.d)=+ f=$(a r.a, b -.e)[-.f a(l +.e, r +.f)]
Examples
In this example, all values less than three are changed to zero, and a list of their keys are produced along with the modified map.
> =a `(map @t @)`(malt ~[['a' 1] ['b' 2] ['c' 3] ['d' 4] ['e' 5]])> a{[p='e' q=5] [p='b' q=2] [p='d' q=4] [p='a' q=1] [p='c' q=3]}> =c |= [[k=@t v=@] acc=(list @t)]?: (lth v 3)[[k acc] [k 0]][acc [k v]]> `[(list @t) (map @t @)]`(~(rib by a) *(list @t) c)[<|a b|> {[p='e' q=5] [p='b' q=0] [p='d' q=4] [p='a' q=0] [p='c' q=3]}]
Discussion
Key-value pairs in the map are transformed in their existing tree location. This means if you change the key, you'd likely produce a map with an incorrect order, so typically you should only change the value.
++run:by
Transform values
Iterates over every value in map a
using gate b
, producing a map.
Accepts
a
is a map, and is the sample of +by
.
b
is a gate.
Produces
A map.
Source
++ run~/ %run|* b=gate|-?~ a a[n=[p=p.n.a q=(b q.n.a)] l=$(a l.a) r=$(a r.a)]
Examples
> =a `(map @t @)`(malt ~[['a' 1] ['b' 2] ['c' 3] ['d' 4] ['e' 5]])> `(map @t @)`(~(run by a) dec){[p='e' q=4] [p='b' q=1] [p='d' q=3] [p='a' q=0] [p='c' q=2]}
++rut:by
Transform nodes
Applies a gate b
to nodes in map a
. The sample of gate b
is a key-value pair, and it produces a new value.
Accepts
a
is a map, and is the sample of +by
.
b
is a gate.
Produces
A map.
Source
++ rut|* b=gate|-?~ a a[n=[p=p.n.a q=(b p.n.a q.n.a)] l=$(a l.a) r=$(a r.a)]
Examples
> =a `(map @ @)`(malt ~[[1 1] [2 2] [3 3] [4 4] [5 5]])> =b |= [k=@ v=@]?: (gth v 2)(mul k v)v> `(map @ @)`(~(rut by a) b){[p=5 q=25] [p=1 q=1] [p=2 q=2] [p=3 q=9] [p=4 q=16]}
++tap:by
Listify pairs
Produces the list of all elements in map a
.
Accepts
a
is a map, and is the sample of +by
.
Produces
A list.
Source
++ tap=< $~/ %tap=+ b=`(list _?>(?=(^ a) n.a))`~|. ^+ b?~ ab$(a r.a, b [n.a $(a l.a)])
Examples
> =a `(map @ @)`(malt ~[[1 1] [2 2] [3 3] [4 4] [5 5]])> ~(tap by a)~[[p=4 q=4] [p=3 q=3] [p=2 q=2] [p=1 q=1] [p=5 q=5]]
++uni:by
Union, merge
Produces a map of the union between the keys of a
and b
. If b
shares a key with a
, the tuple from b
is preserved.
Accepts
a
is a map, and is the sample +by
.
b
is a map.
Produces
A map.
Source
++ uni~/ %uni=+ b=a|@++ $|- ^+ a?~ ba?~ ab?: =(p.n.b p.n.a)b(l $(a l.a, b l.b), r $(a r.a, b r.b))?: (mor p.n.a p.n.b)?: (gor p.n.b p.n.a)$(l.a $(a l.a, r.b ~), b r.b)$(r.a $(a r.a, l.b ~), b l.b)?: (gor p.n.a p.n.b)$(l.b $(b l.b, r.a ~), a r.a)$(r.b $(b r.b, l.a ~), a l.a)--
Examples
> =a `(map @ @)`(malt ~[[1 1] [2 2] [3 3]])> =b `(map @ @)`(malt ~[[3 300] [4 400] [5 500]])> a{[p=1 q=1] [p=2 q=2] [p=3 q=3]}> b{[p=5 q=500] [p=3 q=300] [p=4 q=400]}> `(map @ @)`(~(uni by a) b){[p=5 q=500] [p=1 q=1] [p=2 q=2] [p=3 q=300] [p=4 q=400]}
++uno:by
General union
Produces a map of the union between the keys of a
and b
. If b
shares a key with a
, gate meg
is applied to both and its product is used as the new value of the key in question.
Accepts
a
is a map
, and is the sample of +by
.
b
is a map
, and is the sample of ~(uno by a)
.
meg
is a gate, and is the sample of (~(uno by a) b)
.
Produces
A map
.
Source
++ uno=+ b=a|@++ $|= meg=$-([_p:node _q:node _q:node] _q:node)|- ^+ a?~ ba?~ ab?: =(p.n.b p.n.a):+ [p.n.a (meg p.n.a q.n.a q.n.b)]$(b l.b, a l.a)$(b r.b, a r.a)?: (mor p.n.a p.n.b)?: (gor p.n.b p.n.a)$(l.a $(a l.a, r.b ~), b r.b)$(r.a $(a r.a, l.b ~), b l.b)?: (gor p.n.a p.n.b)$(l.b $(b l.b, r.a ~), a r.a)$(r.b $(b r.b, l.a ~), a l.a)--
Examples
> =a `(map @ @)`(malt ~[[1 1] [2 2] [3 3]])> =b `(map @ @)`(malt ~[[3 3] [4 4] [5 5]])> a{[p=1 q=1] [p=2 q=2] [p=3 q=3]}> b{[p=5 q=5] [p=3 q=3] [p=4 q=4]}> `(map @ @)`((~(uno by a) b) |=([k=@ v=@ w=@] (add v w))){[p=5 q=5] [p=1 q=1] [p=2 q=2] [p=3 q=6] [p=4 q=4]}
++urn:by
Turn (with key)
Iterates over every value in map a
using gate b
, which accepts both the key and the value of each element as its sample.
Accepts
a
is a map.
b
is a gate that accepts two nouns.
Produces
A map
.
Source
++ urn~/ %urn|* b=$-([* *] *)|-?~ a ~a(n n.a(q (b p.n.a q.n.a)), l $(a l.a), r $(a r.a))
Examples
> =a `(map @ @)`(malt ~[[1 1] [2 2] [3 3]])> a{[p=1 q=1] [p=2 q=2] [p=3 q=3]}> (~(urn by a) |=([k=@ v=@] (pow v 2))){[p=1 q=1] [p=2 q=4] [p=3 q=9]}
++wyt:by
Depth
Produce the size of the tree map a
.
Accepts
a
is a map, and is the sample of +by
.
Produces
An atom.
Source
++ wyt=< $~% %wyt + ~|. ^- @?~(a 0 +((add $(a l.a) $(a r.a))))
Examples
> =a `(map @ @)`(malt ~[[1 1] [2 2] [3 3]])> =b `(map @ @)`(malt ~[[1 1] [2 2] [3 3] [4 4] [5 5]])> a{[p=1 q=1] [p=2 q=2] [p=3 q=3]}> b{[p=5 q=5] [p=1 q=1] [p=2 q=2] [p=3 q=3] [p=4 q=4]}> ~(wyt by a)3> ~(wyt by b)5
++val:by
List of values
Produces a list of all values in map a
.
Accepts
a
is a map.
Produces
A list.
Source
++ val=+ b=`(list _?>(?=(^ a) q.n.a))`~|- ^+ b?~ a b$(a r.a, b [q.n.a $(a l.a)])
Examples
> =a `(map @t @)`(malt ~[['a' 1] ['b' 2] ['c' 3]])> a{[p='b' q=2] [p='a' q=1] [p='c' q=3]}> ~(val by a)~[3 1 2]