urbit/pkg/arvo/sys/zuse.hoon
Joe Bryan 9a1b9b4450 Merge branch 'master' into release/next-vere
* master: (595 commits)
  grid: updating glob
  landscape: updating glob
  graph-store: clean up merge artefact
  interface: reduce %all-stats correctly
  docket: correctly en-vase a docket definition
  kiln: don't +mean the tang noun alongside the tang
  hood: scry for list of desks with empty desk name
  hood: remove needless weld
  hood: report %kids desk hash in +report-vats
  landscape: fix joining indicator in statusbar
  interface: reduce %saw-place correctly
  app-prefs: fixing logic around enabled
  pull-hook: add nice flag to kick poke
  graph-pull-hook: renegotiate subscriptions
  graph-store: Handle missing update-logs gracefully in scries
  arvo: update jamfiles
  landscape: correctly freeze graph-update-2
  jael: on rekey, update life if moon
  tmp/ jamfiles
  btc: updating glob
  ...
2021-10-05 11:33:08 -04:00

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:: /sys/zuse
:: %zuse: arvo library
::
=> ..lull
~% %zuse ..part ~
|%
++ zuse %420
:: :: ::
:::: :: :: (2) engines
:: :: ::
:: ::::
:::: ++number :: (2a) number theory
:: ::::
++ number ^?
|%
:: :: ++fu:number
++ fu :: modulo (mul p q)
|= a=[p=@ q=@]
=+ b=?:(=([0 0] a) 0 (~(inv fo p.a) (~(sit fo p.a) q.a)))
|%
:: :: ++dif:fu:number
++ dif :: subtract
|= [c=[@ @] d=[@ @]]
[(~(dif fo p.a) -.c -.d) (~(dif fo q.a) +.c +.d)]
:: :: ++exp:fu:number
++ exp :: exponent
|= [c=@ d=[@ @]]
:- (~(exp fo p.a) (mod c (dec p.a)) -.d)
(~(exp fo q.a) (mod c (dec q.a)) +.d)
:: :: ++out:fu:number
++ out :: garner's formula
|= c=[@ @]
%+ add +.c
%+ mul q.a
%+ ~(pro fo p.a) b
(~(dif fo p.a) -.c (~(sit fo p.a) +.c))
:: :: ++pro:fu:number
++ pro :: multiply
|= [c=[@ @] d=[@ @]]
[(~(pro fo p.a) -.c -.d) (~(pro fo q.a) +.c +.d)]
:: :: ++sum:fu:number
++ sum :: add
|= [c=[@ @] d=[@ @]]
[(~(sum fo p.a) -.c -.d) (~(sum fo q.a) +.c +.d)]
:: :: ++sit:fu:number
++ sit :: represent
|= c=@
[(mod c p.a) (mod c q.a)]
-- ::fu
:: :: ++pram:number
++ pram :: rabin-miller
|= a=@ ^- ?
?: ?| =(0 (end 0 a))
=(1 a)
=+ b=1
|- ^- ?
?: =(512 b)
|
?|(=+(c=+((mul 2 b)) &(!=(a c) =(a (mul c (div a c))))) $(b +(b)))
==
|
=+ ^= b
=+ [s=(dec a) t=0]
|- ^- [s=@ t=@]
?: =(0 (end 0 s))
$(s (rsh 0 s), t +(t))
[s t]
?> =((mul s.b (bex t.b)) (dec a))
=+ c=0
|- ^- ?
?: =(c 64)
&
=+ d=(~(raw og (add c a)) (met 0 a))
=+ e=(~(exp fo a) s.b d)
?& ?| =(1 e)
=+ f=0
|- ^- ?
?: =(e (dec a))
&
?: =(f (dec t.b))
|
$(e (~(pro fo a) e e), f +(f))
==
$(c +(c))
==
:: :: ++ramp:number
++ ramp :: make r-m prime
|= [a=@ b=(list @) c=@] ^- @ux :: [bits snags seed]
=> .(c (shas %ramp c))
=+ d=*@
|-
?: =((mul 100 a) d)
~|(%ar-ramp !!)
=+ e=(~(raw og c) a)
?: &((levy b |=(f=@ !=(1 (mod e f)))) (pram e))
e
$(c +(c), d (shax d))
:: :: ++curt:number
++ curt :: curve25519
|= [a=@ b=@]
=> %= .
+
=> +
=+ =+ [p=486.662 q=(sub (bex 255) 19)]
=+ fq=~(. fo q)
[p=p q=q fq=fq]
|%
:: :: ++cla:curt:number
++ cla ::
|= raw=@
=+ low=(dis 248 (cut 3 [0 1] raw))
=+ hih=(con 64 (dis 127 (cut 3 [31 1] raw)))
=+ mid=(cut 3 [1 30] raw)
(can 3 [[1 low] [30 mid] [1 hih] ~])
:: :: ++sqr:curt:number
++ sqr ::
|=(a=@ (mul a a))
:: :: ++inv:curt:number
++ inv ::
|=(a=@ (~(exp fo q) (sub q 2) a))
:: :: ++cad:curt:number
++ cad ::
|= [n=[x=@ z=@] m=[x=@ z=@] d=[x=@ z=@]]
=+ ^= xx
;: mul 4 z.d
%- sqr %- abs:si
%+ dif:si
(sun:si (mul x.m x.n))
(sun:si (mul z.m z.n))
==
=+ ^= zz
;: mul 4 x.d
%- sqr %- abs:si
%+ dif:si
(sun:si (mul x.m z.n))
(sun:si (mul z.m x.n))
==
[(sit.fq xx) (sit.fq zz)]
:: :: ++cub:curt:number
++ cub ::
|= [x=@ z=@]
=+ ^= xx
%+ mul
%- sqr %- abs:si
(dif:si (sun:si x) (sun:si z))
(sqr (add x z))
=+ ^= zz
;: mul 4 x z
:(add (sqr x) :(mul p x z) (sqr z))
==
[(sit.fq xx) (sit.fq zz)]
-- ::
==
=+ one=[b 1]
=+ i=253
=+ r=one
=+ s=(cub one)
|-
?: =(i 0)
=+ x=(cub r)
(sit.fq (mul -.x (inv +.x)))
=+ m=(rsh [0 i] a)
?: =(0 (mod m 2))
$(i (dec i), s (cad r s one), r (cub r))
$(i (dec i), r (cad r s one), s (cub s))
:: :: ++ga:number
++ ga :: GF (bex p.a)
|= a=[p=@ q=@ r=@] :: dim poly gen
=+ si=(bex p.a)
=+ ma=(dec si)
=> |%
:: :: ++dif:ga:number
++ dif :: add and sub
|= [b=@ c=@]
~| [%dif-ga a]
?> &((lth b si) (lth c si))
(mix b c)
:: :: ++dub:ga:number
++ dub :: mul by x
|= b=@
~| [%dub-ga a]
?> (lth b si)
?: =(1 (cut 0 [(dec p.a) 1] b))
(dif (sit q.a) (sit (lsh 0 b)))
(lsh 0 b)
:: :: ++pro:ga:number
++ pro :: slow multiply
|= [b=@ c=@]
?: =(0 b)
0
?: =(1 (dis 1 b))
(dif c $(b (rsh 0 b), c (dub c)))
$(b (rsh 0 b), c (dub c))
:: :: ++toe:ga:number
++ toe :: exp+log tables
=+ ^= nu
|= [b=@ c=@]
^- (map @ @)
=+ d=*(map @ @)
|-
?: =(0 c)
d
%= $
c (dec c)
d (~(put by d) c b)
==
=+ [p=(nu 0 (bex p.a)) q=(nu ma ma)]
=+ [b=1 c=0]
|- ^- [p=(map @ @) q=(map @ @)]
?: =(ma c)
[(~(put by p) c b) q]
%= $
b (pro r.a b)
c +(c)
p (~(put by p) c b)
q (~(put by q) b c)
==
:: :: ++sit:ga:number
++ sit :: reduce
|= b=@
(mod b (bex p.a))
-- ::
=+ toe
|%
:: :: ++fra:ga:number
++ fra :: divide
|= [b=@ c=@]
(pro b (inv c))
:: :: ++inv:ga:number
++ inv :: invert
|= b=@
~| [%inv-ga a]
=+ c=(~(get by q) b)
?~ c !!
=+ d=(~(get by p) (sub ma u.c))
(need d)
:: :: ++pow:ga:number
++ pow :: exponent
|= [b=@ c=@]
=+ [d=1 e=c f=0]
|-
?: =(p.a f)
d
?: =(1 (cut 0 [f 1] b))
$(d (pro d e), e (pro e e), f +(f))
$(e (pro e e), f +(f))
:: :: ++pro:ga:number
++ pro :: multiply
|= [b=@ c=@]
~| [%pro-ga a]
=+ d=(~(get by q) b)
?~ d 0
=+ e=(~(get by q) c)
?~ e 0
=+ f=(~(get by p) (mod (add u.d u.e) ma))
(need f)
-- ::ga
-- ::number
:: ::::
:::: ++crypto :: (2b) cryptography
:: ::::
++ crypto ^?
=, ames
=, number
|%
:: ::
:::: ++aes:crypto :: (2b1) aes, all sizes
:: ::::
++ aes !.
~% %aes ..part ~
|%
:: :: ++ahem:aes:crypto
++ ahem :: kernel state
|= [nnk=@ nnb=@ nnr=@]
=>
=+ => [gr=(ga 8 0x11b 3) few==>(fe .(a 5))]
[pro=pro.gr dif=dif.gr pow=pow.gr ror=ror.few]
=> |% ::
++ cipa $_ ^? :: AES params
|%
++ co *[p=@ q=@ r=@ s=@] :: column coefficients
++ ix |~(a=@ *@) :: key index
++ ro *[p=@ q=@ r=@ s=@] :: row shifts
++ su *@ :: s-box
-- ::cipa
-- ::
|%
:: :: ++pen:ahem:aes:
++ pen :: encrypt
^- cipa
|%
:: :: ++co:pen:ahem:aes:
++ co :: column coefficients
[0x2 0x3 1 1]
:: :: ++ix:pen:ahem:aes:
++ ix :: key index
|~(a=@ a)
:: :: ++ro:pen:ahem:aes:
++ ro :: row shifts
[0 1 2 3]
:: :: ++su:pen:ahem:aes:
++ su :: s-box
0x16bb.54b0.0f2d.9941.6842.e6bf.0d89.a18c.
df28.55ce.e987.1e9b.948e.d969.1198.f8e1.
9e1d.c186.b957.3561.0ef6.0348.66b5.3e70.
8a8b.bd4b.1f74.dde8.c6b4.a61c.2e25.78ba.
08ae.7a65.eaf4.566c.a94e.d58d.6d37.c8e7.
79e4.9591.62ac.d3c2.5c24.0649.0a3a.32e0.
db0b.5ede.14b8.ee46.8890.2a22.dc4f.8160.
7319.5d64.3d7e.a7c4.1744.975f.ec13.0ccd.
d2f3.ff10.21da.b6bc.f538.9d92.8f40.a351.
a89f.3c50.7f02.f945.8533.4d43.fbaa.efd0.
cf58.4c4a.39be.cb6a.5bb1.fc20.ed00.d153.
842f.e329.b3d6.3b52.a05a.6e1b.1a2c.8309.
75b2.27eb.e280.1207.9a05.9618.c323.c704.
1531.d871.f1e5.a534.ccf7.3f36.2693.fdb7.
c072.a49c.afa2.d4ad.f047.59fa.7dc9.82ca.
76ab.d7fe.2b67.0130.c56f.6bf2.7b77.7c63
--
:: :: ++pin:ahem:aes:
++ pin :: decrypt
^- cipa
|%
:: :: ++co:pin:ahem:aes:
++ co :: column coefficients
[0xe 0xb 0xd 0x9]
:: :: ++ix:pin:ahem:aes:
++ ix :: key index
|~(a=@ (sub nnr a))
:: :: ++ro:pin:ahem:aes:
++ ro :: row shifts
[0 3 2 1]
:: :: ++su:pin:ahem:aes:
++ su :: s-box
0x7d0c.2155.6314.69e1.26d6.77ba.7e04.2b17.
6199.5383.3cbb.ebc8.b0f5.2aae.4d3b.e0a0.
ef9c.c993.9f7a.e52d.0d4a.b519.a97f.5160.
5fec.8027.5910.12b1.31c7.0788.33a8.dd1f.
f45a.cd78.fec0.db9a.2079.d2c6.4b3e.56fc.
1bbe.18aa.0e62.b76f.89c5.291d.711a.f147.
6edf.751c.e837.f9e2.8535.ade7.2274.ac96.
73e6.b4f0.cecf.f297.eadc.674f.4111.913a.
6b8a.1301.03bd.afc1.020f.3fca.8f1e.2cd0.
0645.b3b8.0558.e4f7.0ad3.bc8c.00ab.d890.
849d.8da7.5746.155e.dab9.edfd.5048.706c.
92b6.655d.cc5c.a4d4.1698.6886.64f6.f872.
25d1.8b6d.49a2.5b76.b224.d928.66a1.2e08.
4ec3.fa42.0b95.4cee.3d23.c2a6.3294.7b54.
cbe9.dec4.4443.8e34.87ff.2f9b.8239.e37c.
fbd7.f381.9ea3.40bf.38a5.3630.d56a.0952
--
:: :: ++mcol:ahem:aes:
++ mcol ::
|= [a=(list @) b=[p=@ q=@ r=@ s=@]]
^- (list @)
=+ c=[p=*@ q=*@ r=*@ s=*@]
|- ^- (list @)
?~ a ~
=> .(p.c (cut 3 [0 1] i.a))
=> .(q.c (cut 3 [1 1] i.a))
=> .(r.c (cut 3 [2 1] i.a))
=> .(s.c (cut 3 [3 1] i.a))
:_ $(a t.a)
%+ rep 3
%+ turn
%- limo
:~ [[p.c p.b] [q.c q.b] [r.c r.b] [s.c s.b]]
[[p.c s.b] [q.c p.b] [r.c q.b] [s.c r.b]]
[[p.c r.b] [q.c s.b] [r.c p.b] [s.c q.b]]
[[p.c q.b] [q.c r.b] [r.c s.b] [s.c p.b]]
==
|= [a=[@ @] b=[@ @] c=[@ @] d=[@ @]]
:(dif (pro a) (pro b) (pro c) (pro d))
:: :: ++pode:ahem:aes:
++ pode :: explode to block
|= [a=bloq b=@ c=@] ^- (list @)
=+ d=(rip a c)
=+ m=(met a c)
|-
?: =(m b)
d
$(m +(m), d (weld d (limo [0 ~])))
:: :: ++sube:ahem:aes:
++ sube :: s-box word
|= [a=@ b=@] ^- @
(rep 3 (turn (pode 3 4 a) |=(c=@ (cut 3 [c 1] b))))
-- ::
|%
:: :: ++be:ahem:aes:crypto
++ be :: block cipher
|= [a=? b=@ c=@H] ^- @uxH
~| %be-aesc
=> %= .
+
=> +
|%
:: :: ++ankh:be:ahem:aes:
++ ankh ::
|= [a=cipa b=@ c=@]
(pode 5 nnb (cut 5 [(mul (ix.a b) nnb) nnb] c))
:: :: ++sark:be:ahem:aes:
++ sark ::
|= [c=(list @) d=(list @)]
^- (list @)
?~ c ~
?~ d !!
[(mix i.c i.d) $(c t.c, d t.d)]
:: :: ++srow:be:ahem:aes:
++ srow ::
|= [a=cipa b=(list @)] ^- (list @)
=+ [c=0 d=~ e=ro.a]
|-
?: =(c nnb)
d
:_ $(c +(c))
%+ rep 3
%+ turn
(limo [0 p.e] [1 q.e] [2 r.e] [3 s.e] ~)
|= [f=@ g=@]
(cut 3 [f 1] (snag (mod (add g c) nnb) b))
:: :: ++subs:be:ahem:aes:
++ subs ::
|= [a=cipa b=(list @)] ^- (list @)
?~ b ~
[(sube i.b su.a) $(b t.b)]
--
==
=+ [d=?:(a pen pin) e=(pode 5 nnb c) f=1]
=> .(e (sark e (ankh d 0 b)))
|-
?. =(nnr f)
=> .(e (subs d e))
=> .(e (srow d e))
=> .(e (mcol e co.d))
=> .(e (sark e (ankh d f b)))
$(f +(f))
=> .(e (subs d e))
=> .(e (srow d e))
=> .(e (sark e (ankh d nnr b)))
(rep 5 e)
:: :: ++ex:ahem:aes:crypto
++ ex :: key expand
|= a=@I ^- @
=+ [b=a c=0 d=su:pen i=nnk]
|-
?: =(i (mul nnb +(nnr)))
b
=> .(c (cut 5 [(dec i) 1] b))
=> ?: =(0 (mod i nnk))
=> .(c (ror 3 1 c))
=> .(c (sube c d))
.(c (mix c (pow (dec (div i nnk)) 2)))
?: &((gth nnk 6) =(4 (mod i nnk)))
.(c (sube c d))
.
=> .(c (mix c (cut 5 [(sub i nnk) 1] b)))
=> .(b (can 5 [i b] [1 c] ~))
$(i +(i))
:: :: ++ix:ahem:aes:crypto
++ ix :: key expand, inv
|= a=@ ^- @
=+ [i=1 j=*@ b=*@ c=co:pin]
|-
?: =(nnr i)
a
=> .(b (cut 7 [i 1] a))
=> .(b (rep 5 (mcol (pode 5 4 b) c)))
=> .(j (sub nnr i))
%= $
i +(i)
a
%+ can 7
:~ [i (cut 7 [0 i] a)]
[1 b]
[j (cut 7 [+(i) j] a)]
==
==
--
:: :: ++ecba:aes:crypto
++ ecba :: AES-128 ECB
~% %ecba +> ~
|_ key=@H
:: :: ++en:ecba:aes:crypto
++ en :: encrypt
~/ %en
|= blk=@H ^- @uxH
=+ (ahem 4 4 10)
=:
key (~(net fe 7) key)
blk (~(net fe 7) blk)
==
%- ~(net fe 7)
(be & (ex key) blk)
:: :: ++de:ecba:aes:crypto
++ de :: decrypt
~/ %de
|= blk=@H ^- @uxH
=+ (ahem 4 4 10)
=:
key (~(net fe 7) key)
blk (~(net fe 7) blk)
==
%- ~(net fe 7)
(be | (ix (ex key)) blk)
-- ::ecba
:: :: ++ecbb:aes:crypto
++ ecbb :: AES-192 ECB
~% %ecbb +> ~
|_ key=@I
:: :: ++en:ecbb:aes:crypto
++ en :: encrypt
~/ %en
|= blk=@H ^- @uxH
=+ (ahem 6 4 12)
=:
key (rsh 6 (~(net fe 8) key))
blk (~(net fe 7) blk)
==
%- ~(net fe 7)
(be & (ex key) blk)
:: :: ++de:ecbb:aes:crypto
++ de :: decrypt
~/ %de
|= blk=@H ^- @uxH
=+ (ahem 6 4 12)
=:
key (rsh 6 (~(net fe 8) key))
blk (~(net fe 7) blk)
==
%- ~(net fe 7)
(be | (ix (ex key)) blk)
-- ::ecbb
:: :: ++ecbc:aes:crypto
++ ecbc :: AES-256 ECB
~% %ecbc +> ~
|_ key=@I
:: :: ++en:ecbc:aes:crypto
++ en :: encrypt
~/ %en
|= blk=@H ^- @uxH
=+ (ahem 8 4 14)
=:
key (~(net fe 8) key)
blk (~(net fe 7) blk)
==
%- ~(net fe 7)
(be & (ex key) blk)
:: :: ++de:ecbc:aes:crypto
++ de :: decrypt
~/ %de
|= blk=@H ^- @uxH
=+ (ahem 8 4 14)
=:
key (~(net fe 8) key)
blk (~(net fe 7) blk)
==
%- ~(net fe 7)
(be | (ix (ex key)) blk)
-- ::ecbc
:: :: ++cbca:aes:crypto
++ cbca :: AES-128 CBC
~% %cbca +> ~
|_ [key=@H prv=@H]
:: :: ++en:cbca:aes:crypto
++ en :: encrypt
~/ %en
|= txt=@ ^- @ux
=+ pts=?:(=(txt 0) `(list @)`~[0] (flop (rip 7 txt)))
=| cts=(list @)
%+ rep 7
:: logically, flop twice here
|- ^- (list @)
?~ pts
cts
=+ cph=(~(en ecba key) (mix prv i.pts))
%= $
cts [cph cts]
pts t.pts
prv cph
==
:: :: ++de:cbca:aes:crypto
++ de :: decrypt
~/ %de
|= txt=@ ^- @ux
=+ cts=?:(=(txt 0) `(list @)`~[0] (flop (rip 7 txt)))
=| pts=(list @)
%+ rep 7
:: logically, flop twice here
|- ^- (list @)
?~ cts
pts
=+ pln=(mix prv (~(de ecba key) i.cts))
%= $
pts [pln pts]
cts t.cts
prv i.cts
==
-- ::cbca
:: :: ++cbcb:aes:crypto
++ cbcb :: AES-192 CBC
~% %cbcb +> ~
|_ [key=@I prv=@H]
:: :: ++en:cbcb:aes:crypto
++ en :: encrypt
~/ %en
|= txt=@ ^- @ux
=+ pts=?:(=(txt 0) `(list @)`~[0] (flop (rip 7 txt)))
=| cts=(list @)
%+ rep 7
:: logically, flop twice here
|- ^- (list @)
?~ pts
cts
=+ cph=(~(en ecbb key) (mix prv i.pts))
%= $
cts [cph cts]
pts t.pts
prv cph
==
:: :: ++de:cbcb:aes:crypto
++ de :: decrypt
~/ %de
|= txt=@ ^- @ux
=+ cts=?:(=(txt 0) `(list @)`~[0] (flop (rip 7 txt)))
=| pts=(list @)
%+ rep 7
:: logically, flop twice here
|- ^- (list @)
?~ cts
pts
=+ pln=(mix prv (~(de ecbb key) i.cts))
%= $
pts [pln pts]
cts t.cts
prv i.cts
==
-- ::cbcb
:: :: ++cbcc:aes:crypto
++ cbcc :: AES-256 CBC
~% %cbcc +> ~
|_ [key=@I prv=@H]
:: :: ++en:cbcc:aes:crypto
++ en :: encrypt
~/ %en
|= txt=@ ^- @ux
=+ pts=?:(=(txt 0) `(list @)`~[0] (flop (rip 7 txt)))
=| cts=(list @)
%+ rep 7
:: logically, flop twice here
|- ^- (list @)
?~ pts
cts
=+ cph=(~(en ecbc key) (mix prv i.pts))
%= $
cts [cph cts]
pts t.pts
prv cph
==
:: :: ++de:cbcc:aes:crypto
++ de :: decrypt
~/ %de
|= txt=@ ^- @ux
=+ cts=?:(=(txt 0) `(list @)`~[0] (flop (rip 7 txt)))
=| pts=(list @)
%+ rep 7
:: logically, flop twice here
|- ^- (list @)
?~ cts
pts
=+ pln=(mix prv (~(de ecbc key) i.cts))
%= $
pts [pln pts]
cts t.cts
prv i.cts
==
-- ::cbcc
:: :: ++inc:aes:crypto
++ inc :: inc. low bloq
|= [mod=bloq ctr=@H]
^- @uxH
=+ bqs=(rip mod ctr)
?~ bqs 0x1
%+ rep mod
[(~(sum fe mod) i.bqs 1) t.bqs]
:: :: ++ctra:aes:crypto
++ ctra :: AES-128 CTR
~% %ctra +> ~
|_ [key=@H mod=bloq len=@ ctr=@H]
:: :: ++en:ctra:aes:crypto
++ en :: encrypt
~/ %en
|= txt=@
^- @ux
=/ encrypt ~(en ecba key)
=/ blocks (add (div len 16) ?:(=((^mod len 16) 0) 0 1))
?> (gte len (met 3 txt))
%+ mix txt
%+ rsh [3 (sub (mul 16 blocks) len)]
%+ rep 7
=| seed=(list @ux)
|- ^+ seed
?: =(blocks 0) seed
%= $
seed [(encrypt ctr) seed]
ctr (inc mod ctr)
blocks (dec blocks)
==
:: :: ++de:ctra:aes:crypto
++ de :: decrypt
en
-- ::ctra
:: :: ++ctrb:aes:crypto
++ ctrb :: AES-192 CTR
~% %ctrb +> ~
|_ [key=@I mod=bloq len=@ ctr=@H]
:: :: ++en:ctrb:aes:crypto
++ en
~/ %en
|= txt=@
^- @ux
=/ encrypt ~(en ecbb key)
=/ blocks (add (div len 16) ?:(=((^mod len 16) 0) 0 1))
?> (gte len (met 3 txt))
%+ mix txt
%+ rsh [3 (sub (mul 16 blocks) len)]
%+ rep 7
=| seed=(list @ux)
|- ^+ seed
?: =(blocks 0) seed
%= $
seed [(encrypt ctr) seed]
ctr (inc mod ctr)
blocks (dec blocks)
==
:: :: ++de:ctrb:aes:crypto
++ de :: decrypt
en
-- ::ctrb
:: :: ++ctrc:aes:crypto
++ ctrc :: AES-256 CTR
~% %ctrc +> ~
|_ [key=@I mod=bloq len=@ ctr=@H]
:: :: ++en:ctrc:aes:crypto
++ en :: encrypt
~/ %en
|= txt=@
^- @ux
=/ encrypt ~(en ecbc key)
=/ blocks (add (div len 16) ?:(=((^mod len 16) 0) 0 1))
?> (gte len (met 3 txt))
%+ mix txt
%+ rsh [3 (sub (mul 16 blocks) len)]
%+ rep 7
=| seed=(list @ux)
|- ^+ seed
?: =(blocks 0) seed
%= $
seed [(encrypt ctr) seed]
ctr (inc mod ctr)
blocks (dec blocks)
==
:: :: ++de:ctrc:aes:crypto
++ de :: decrypt
en
-- ::ctrc
:: :: ++doub:aes:crypto
++ doub :: double 128-bit
|= :: string mod finite
::
str=@H
::
:: field (see spec)
::
^- @uxH
%- ~(sit fe 7)
?. =((xeb str) 128)
(lsh 0 str)
(mix 0x87 (lsh 0 str))
:: :: ++mpad:aes:crypto
++ mpad ::
|= [oct=@ txt=@]
::
:: pad message to multiple of 128 bits
:: by appending 1, then 0s
:: the spec is unclear, but it must be octet based
:: to match the test vectors
::
^- @ux
=+ pad=(mod oct 16)
?: =(pad 0) 0x8000.0000.0000.0000.0000.0000.0000.0000
(lsh [3 (sub 15 pad)] (mix 0x80 (lsh 3 txt)))
:: :: ++suba:aes:crypto
++ suba :: AES-128 subkeys
|= key=@H
=+ l=(~(en ecba key) 0)
=+ k1=(doub l)
=+ k2=(doub k1)
^- [@ux @ux]
[k1 k2]
:: :: ++subb:aes:crypto
++ subb :: AES-192 subkeys
|= key=@I
=+ l=(~(en ecbb key) 0)
=+ k1=(doub l)
=+ k2=(doub k1)
^- [@ux @ux]
[k1 k2]
:: :: ++subc:aes:crypto
++ subc :: AES-256 subkeys
|= key=@I
=+ l=(~(en ecbc key) 0)
=+ k1=(doub l)
=+ k2=(doub k1)
^- [@ux @ux]
[k1 k2]
:: :: ++maca:aes:crypto
++ maca :: AES-128 CMAC
~/ %maca
|= [key=@H oct=(unit @) txt=@]
^- @ux
=+ [sub=(suba key) len=?~(oct (met 3 txt) u.oct)]
=+ ^= pdt
?: &(=((mod len 16) 0) !=(len 0))
[& txt]
[| (mpad len txt)]
=+ ^= mac
%- ~(en cbca key 0)
%+ mix +.pdt
?- -.pdt
%& -.sub
%| +.sub
==
:: spec says MSBs, LSBs match test vectors
::
(~(sit fe 7) mac)
:: :: ++macb:aes:crypto
++ macb :: AES-192 CMAC
~/ %macb
|= [key=@I oct=(unit @) txt=@]
^- @ux
=+ [sub=(subb key) len=?~(oct (met 3 txt) u.oct)]
=+ ^= pdt
?: &(=((mod len 16) 0) !=(len 0))
[& txt]
[| (mpad len txt)]
=+ ^= mac
%- ~(en cbcb key 0)
%+ mix +.pdt
?- -.pdt
%& -.sub
%| +.sub
==
:: spec says MSBs, LSBs match test vectors
::
(~(sit fe 7) mac)
:: :: ++macc:aes:crypto
++ macc :: AES-256 CMAC
~/ %macc
|= [key=@I oct=(unit @) txt=@]
^- @ux
=+ [sub=(subc key) len=?~(oct (met 3 txt) u.oct)]
=+ ^= pdt
?: &(=((mod len 16) 0) !=(len 0))
[& txt]
[| (mpad len txt)]
=+ ^= mac
%- ~(en cbcc key 0)
%+ mix +.pdt
?- -.pdt
%& -.sub
%| +.sub
==
:: spec says MSBs, LSBs match test vectors
::
(~(sit fe 7) mac)
:: :: ++s2va:aes:crypto
++ s2va :: AES-128 S2V
~/ %s2va
|= [key=@H ads=(list @)]
?~ ads (maca key `16 0x1)
=/ res (maca key `16 0x0)
%+ maca key
|- ^- [[~ @ud] @uxH]
?~ t.ads
=/ wyt (met 3 i.ads)
?: (gte wyt 16)
[`wyt (mix i.ads res)]
[`16 (mix (doub res) (mpad wyt i.ads))]
%= $
ads t.ads
res (mix (doub res) (maca key ~ i.ads))
==
:: :: ++s2vb:aes:crypto
++ s2vb :: AES-192 S2V
~/ %s2vb
|= [key=@I ads=(list @)]
?~ ads (macb key `16 0x1)
=/ res (macb key `16 0x0)
%+ macb key
|- ^- [[~ @ud] @uxH]
?~ t.ads
=/ wyt (met 3 i.ads)
?: (gte wyt 16)
[`wyt (mix i.ads res)]
[`16 (mix (doub res) (mpad wyt i.ads))]
%= $
ads t.ads
res (mix (doub res) (macb key ~ i.ads))
==
:: :: ++s2vc:aes:crypto
++ s2vc :: AES-256 S2V
~/ %s2vc
|= [key=@I ads=(list @)]
?~ ads (macc key `16 0x1)
=/ res (macc key `16 0x0)
%+ macc key
|- ^- [[~ @ud] @uxH]
?~ t.ads
=/ wyt (met 3 i.ads)
?: (gte wyt 16)
[`wyt (mix i.ads res)]
[`16 (mix (doub res) (mpad wyt i.ads))]
%= $
ads t.ads
res (mix (doub res) (macc key ~ i.ads))
==
:: :: ++siva:aes:crypto
++ siva :: AES-128 SIV
~% %siva +> ~
|_ [key=@I vec=(list @)]
:: :: ++en:siva:aes:crypto
++ en :: encrypt
~/ %en
|= txt=@
^- (trel @uxH @ud @ux)
=+ [k1=(rsh 7 key) k2=(end 7 key)]
=+ iv=(s2va k1 (weld vec (limo ~[txt])))
=+ len=(met 3 txt)
=* hib (dis iv 0xffff.ffff.ffff.ffff.7fff.ffff.7fff.ffff)
:+
iv
len
(~(en ctra k2 7 len hib) txt)
:: :: ++de:siva:aes:crypto
++ de :: decrypt
~/ %de
|= [iv=@H len=@ txt=@]
^- (unit @ux)
=+ [k1=(rsh 7 key) k2=(end 7 key)]
=* hib (dis iv 0xffff.ffff.ffff.ffff.7fff.ffff.7fff.ffff)
=+ ^= pln
(~(de ctra k2 7 len hib) txt)
?. =((s2va k1 (weld vec (limo ~[pln]))) iv)
~
`pln
-- ::siva
:: :: ++sivb:aes:crypto
++ sivb :: AES-192 SIV
~% %sivb +> ~
|_ [key=@J vec=(list @)]
:: :: ++en:sivb:aes:crypto
++ en :: encrypt
~/ %en
|= txt=@
^- (trel @uxH @ud @ux)
=+ [k1=(rsh [6 3] key) k2=(end [6 3] key)]
=+ iv=(s2vb k1 (weld vec (limo ~[txt])))
=* hib (dis iv 0xffff.ffff.ffff.ffff.7fff.ffff.7fff.ffff)
=+ len=(met 3 txt)
:+ iv
len
(~(en ctrb k2 7 len hib) txt)
:: :: ++de:sivb:aes:crypto
++ de :: decrypt
~/ %de
|= [iv=@H len=@ txt=@]
^- (unit @ux)
=+ [k1=(rsh [6 3] key) k2=(end [6 3] key)]
=* hib (dis iv 0xffff.ffff.ffff.ffff.7fff.ffff.7fff.ffff)
=+ ^= pln
(~(de ctrb k2 7 len hib) txt)
?. =((s2vb k1 (weld vec (limo ~[pln]))) iv)
~
`pln
-- ::sivb
:: :: ++sivc:aes:crypto
++ sivc :: AES-256 SIV
~% %sivc +> ~
|_ [key=@J vec=(list @)]
:: :: ++en:sivc:aes:crypto
++ en :: encrypt
~/ %en
|= txt=@
^- (trel @uxH @ud @ux)
=+ [k1=(rsh 8 key) k2=(end 8 key)]
=+ iv=(s2vc k1 (weld vec (limo ~[txt])))
=* hib (dis iv 0xffff.ffff.ffff.ffff.7fff.ffff.7fff.ffff)
=+ len=(met 3 txt)
:+
iv
len
(~(en ctrc k2 7 len hib) txt)
:: :: ++de:sivc:aes:crypto
++ de :: decrypt
~/ %de
|= [iv=@H len=@ txt=@]
^- (unit @ux)
=+ [k1=(rsh 8 key) k2=(end 8 key)]
=* hib (dis iv 0xffff.ffff.ffff.ffff.7fff.ffff.7fff.ffff)
=+ ^= pln
(~(de ctrc k2 7 len hib) txt)
?. =((s2vc k1 (weld vec (limo ~[pln]))) iv)
~
`pln
-- ::sivc
--
:: ::
:::: ++ed:crypto :: ed25519
:: ::::
++ ed
=>
=+ =+ [b=256 q=(sub (bex 255) 19)]
=+ fq=~(. fo q)
=+ ^= l
%+ add
(bex 252)
27.742.317.777.372.353.535.851.937.790.883.648.493
=+ d=(dif.fq 0 (fra.fq 121.665 121.666))
=+ ii=(exp.fq (div (dec q) 4) 2)
[b=b q=q fq=fq l=l d=d ii=ii]
~% %coed ..part ~
|%
:: :: ++norm:ed:crypto
++ norm ::
|=(x=@ ?:(=(0 (mod x 2)) x (sub q x)))
:: :: ++xrec:ed:crypto
++ xrec :: recover x-coord
|= y=@ ^- @
=+ ^= xx
%+ mul (dif.fq (mul y y) 1)
(inv.fq +(:(mul d y y)))
=+ x=(exp.fq (div (add 3 q) 8) xx)
?: !=(0 (dif.fq (mul x x) (sit.fq xx)))
(norm (pro.fq x ii))
(norm x)
:: :: ++ward:ed:crypto
++ ward :: edwards multiply
|= [pp=[@ @] qq=[@ @]] ^- [@ @]
=+ dp=:(pro.fq d -.pp -.qq +.pp +.qq)
=+ ^= xt
%+ pro.fq
%+ sum.fq
(pro.fq -.pp +.qq)
(pro.fq -.qq +.pp)
(inv.fq (sum.fq 1 dp))
=+ ^= yt
%+ pro.fq
%+ sum.fq
(pro.fq +.pp +.qq)
(pro.fq -.pp -.qq)
(inv.fq (dif.fq 1 dp))
[xt yt]
:: :: ++scam:ed:crypto
++ scam :: scalar multiply
|= [pp=[@ @] e=@] ^- [@ @]
?: =(0 e)
[0 1]
=+ qq=$(e (div e 2))
=> .(qq (ward qq qq))
?: =(1 (dis 1 e))
(ward qq pp)
qq
:: :: ++etch:ed:crypto
++ etch :: encode point
|= pp=[@ @] ^- @
(can 0 ~[[(sub b 1) +.pp] [1 (dis 1 -.pp)]])
:: :: ++curv:ed:crypto
++ curv :: point on curve?
|= [x=@ y=@] ^- ?
.= 0
%+ dif.fq
%+ sum.fq
(pro.fq (sub q (sit.fq x)) x)
(pro.fq y y)
(sum.fq 1 :(pro.fq d x x y y))
:: :: ++deco:ed:crypto
++ deco :: decode point
|= s=@ ^- (unit [@ @])
=+ y=(cut 0 [0 (dec b)] s)
=+ si=(cut 0 [(dec b) 1] s)
=+ x=(xrec y)
=> .(x ?:(!=(si (dis 1 x)) (sub q x) x))
=+ pp=[x y]
?. (curv pp)
~
[~ pp]
:: :: ++bb:ed:crypto
++ bb ::
=+ bby=(pro.fq 4 (inv.fq 5))
[(xrec bby) bby]
-- ::
~% %ed + ~
|%
::
++ point-add
~/ %point-add
|= [a-point=@udpoint b-point=@udpoint]
^- @udpoint
::
=/ a-point-decoded=[@ @] (need (deco a-point))
=/ b-point-decoded=[@ @] (need (deco b-point))
::
%- etch
(ward a-point-decoded b-point-decoded)
::
++ scalarmult
~/ %scalarmult
|= [a=@udscalar a-point=@udpoint]
^- @udpoint
::
=/ a-point-decoded=[@ @] (need (deco a-point))
::
%- etch
(scam a-point-decoded a)
::
++ scalarmult-base
~/ %scalarmult-base
|= scalar=@udscalar
^- @udpoint
%- etch
(scam bb scalar)
::
++ add-scalarmult-scalarmult-base
~/ %add-scalarmult-scalarmult-base
|= [a=@udscalar a-point=@udpoint b=@udscalar]
^- @udpoint
::
=/ a-point-decoded=[@ @] (need (deco a-point))
::
%- etch
%+ ward
(scam bb b)
(scam a-point-decoded a)
::
++ add-double-scalarmult
~/ %add-double-scalarmult
|= [a=@udscalar a-point=@udpoint b=@udscalar b-point=@udpoint]
^- @udpoint
::
=/ a-point-decoded=[@ @] (need (deco a-point))
=/ b-point-decoded=[@ @] (need (deco b-point))
::
%- etch
%+ ward
(scam a-point-decoded a)
(scam b-point-decoded b)
:: :: ++puck:ed:crypto
++ puck :: public key
~/ %puck
|= sk=@I ^- @
?: (gth (met 3 sk) 32) !!
=+ h=(shal (rsh [0 3] b) sk)
=+ ^= a
%+ add
(bex (sub b 2))
(lsh [0 3] (cut 0 [3 (sub b 5)] h))
=+ aa=(scam bb a)
(etch aa)
:: :: ++suck:ed:crypto
++ suck :: keypair from seed
|= se=@I ^- @uJ
=+ pu=(puck se)
(can 0 ~[[b se] [b pu]])
:: :: ++shar:ed:crypto
++ shar :: curve25519 secret
~/ %shar
|= [pub=@ sek=@]
^- @ux
=+ exp=(shal (rsh [0 3] b) (suck sek))
=. exp (dis exp (can 0 ~[[3 0] [251 (fil 0 251 1)]]))
=. exp (con exp (lsh [3 31] 0b100.0000))
=+ prv=(end 8 exp)
=+ crv=(fra.fq (sum.fq 1 pub) (dif.fq 1 pub))
(curt prv crv)
:: :: ++sign:ed:crypto
++ sign :: certify
~/ %sign
|= [m=@ se=@] ^- @
=+ sk=(suck se)
=+ pk=(cut 0 [b b] sk)
=+ h=(shal (rsh [0 3] b) sk)
=+ ^= a
%+ add
(bex (sub b 2))
(lsh [0 3] (cut 0 [3 (sub b 5)] h))
=+ ^= r
=+ hm=(cut 0 [b b] h)
=+ ^= i
%+ can 0
:~ [b hm]
[(met 0 m) m]
==
(shaz i)
=+ rr=(scam bb r)
=+ ^= ss
=+ er=(etch rr)
=+ ^= ha
%+ can 0
:~ [b er]
[b pk]
[(met 0 m) m]
==
(~(sit fo l) (add r (mul (shaz ha) a)))
(can 0 ~[[b (etch rr)] [b ss]])
:: :: ++veri:ed:crypto
++ veri :: validate
~/ %veri
|= [s=@ m=@ pk=@] ^- ?
?: (gth (div b 4) (met 3 s)) |
?: (gth (div b 8) (met 3 pk)) |
=+ cb=(rsh [0 3] b)
=+ rr=(deco (cut 0 [0 b] s))
?~ rr |
=+ aa=(deco pk)
?~ aa |
=+ ss=(cut 0 [b b] s)
=+ ha=(can 3 ~[[cb (etch u.rr)] [cb pk] [(met 3 m) m]])
=+ h=(shaz ha)
=((scam bb ss) (ward u.rr (scam u.aa h)))
-- ::ed
:: ::
:::: ++scr:crypto :: (2b3) scrypt
:: ::::
++ scr
~% %scr ..part ~
|%
:: :: ++sal:scr:crypto
++ sal :: salsa20 hash
|= [x=@ r=@] :: with r rounds
?> =((mod r 2) 0) ::
=+ few==>(fe .(a 5))
=+ ^= rot
|= [a=@ b=@]
(mix (end 5 (lsh [0 a] b)) (rsh [0 (sub 32 a)] b))
=+ ^= lea
|= [a=@ b=@]
(net:few (sum:few (net:few a) (net:few b)))
=> |%
:: :: ++qr:sal:scr:crypto
++ qr :: quarterround
|= y=[@ @ @ @ ~]
=+ zb=(mix &2.y (rot 7 (sum:few &1.y &4.y)))
=+ zc=(mix &3.y (rot 9 (sum:few zb &1.y)))
=+ zd=(mix &4.y (rot 13 (sum:few zc zb)))
=+ za=(mix &1.y (rot 18 (sum:few zd zc)))
~[za zb zc zd]
:: :: ++rr:sal:scr:crypto
++ rr :: rowround
|= [y=(list @)]
=+ za=(qr ~[&1.y &2.y &3.y &4.y])
=+ zb=(qr ~[&6.y &7.y &8.y &5.y])
=+ zc=(qr ~[&11.y &12.y &9.y &10.y])
=+ zd=(qr ~[&16.y &13.y &14.y &15.y])
^- (list @) :~
&1.za &2.za &3.za &4.za
&4.zb &1.zb &2.zb &3.zb
&3.zc &4.zc &1.zc &2.zc
&2.zd &3.zd &4.zd &1.zd ==
:: :: ++cr:sal:scr:crypto
++ cr :: columnround
|= [x=(list @)]
=+ ya=(qr ~[&1.x &5.x &9.x &13.x])
=+ yb=(qr ~[&6.x &10.x &14.x &2.x])
=+ yc=(qr ~[&11.x &15.x &3.x &7.x])
=+ yd=(qr ~[&16.x &4.x &8.x &12.x])
^- (list @) :~
&1.ya &4.yb &3.yc &2.yd
&2.ya &1.yb &4.yc &3.yd
&3.ya &2.yb &1.yc &4.yd
&4.ya &3.yb &2.yc &1.yd ==
:: :: ++dr:sal:scr:crypto
++ dr :: doubleround
|= [x=(list @)]
(rr (cr x))
:: :: ++al:sal:scr:crypto
++ al :: add two lists
|= [a=(list @) b=(list @)]
|- ^- (list @)
?~ a ~ ?~ b ~
[i=(sum:few -.a -.b) t=$(a +.a, b +.b)]
-- ::
=+ xw=(rpp 5 16 x)
=+ ^= ow |- ^- (list @)
?~ r xw
$(xw (dr xw), r (sub r 2))
(rep 5 (al xw ow))
:: :: ++rpp:scr:crypto
++ rpp :: rip+filler blocks
|= [a=bloq b=@ c=@]
=+ q=(rip a c)
=+ w=(lent q)
?. =(w b)
?. (lth w b) (slag (sub w b) q)
^+ q (weld q (reap (sub b (lent q)) 0))
q
:: :: ++bls:scr:crypto
++ bls :: split to sublists
|= [a=@ b=(list @)]
?> =((mod (lent b) a) 0)
|- ^- (list (list @))
?~ b ~
[i=(scag a `(list @)`b) t=$(b (slag a `(list @)`b))]
:: :: ++slb:scr:crypto
++ slb ::
|= [a=(list (list @))]
|- ^- (list @)
?~ a ~
(weld `(list @)`-.a $(a +.a))
:: :: ++sbm:scr:crypto
++ sbm :: scryptBlockMix
|= [r=@ b=(list @)]
?> =((lent b) (mul 2 r))
=+ [x=(snag (dec (mul 2 r)) b) c=0]
=| [ya=(list @) yb=(list @)]
|- ^- (list @)
?~ b (flop (weld yb ya))
=. x (sal (mix x -.b) 8)
?~ (mod c 2)
$(c +(c), b +.b, ya [i=x t=ya])
$(c +(c), b +.b, yb [i=x t=yb])
:: :: ++srm:scr:crypto
++ srm :: scryptROMix
|= [r=@ b=(list @) n=@]
?> ?& =((lent b) (mul 2 r))
=(n (bex (dec (xeb n))))
(lth n (bex (mul r 16)))
==
=+ [v=*(list (list @)) c=0]
=. v
|- ^- (list (list @))
=+ w=(sbm r b)
?: =(c n) (flop v)
$(c +(c), v [i=[b] t=v], b w)
=+ x=(sbm r (snag (dec n) v))
|- ^- (list @)
?: =(c n) x
=+ q=(snag (dec (mul r 2)) x)
=+ z=`(list @)`(snag (mod q n) v)
=+ ^= w |- ^- (list @)
?~ x ~ ?~ z ~
[i=(mix -.x -.z) t=$(x +.x, z +.z)]
$(x (sbm r w), c +(c))
:: :: ++hmc:scr:crypto
++ hmc :: HMAC-SHA-256
|= [k=@ t=@]
(hml k (met 3 k) t (met 3 t))
:: :: ++hml:scr:crypto
++ hml :: w+length
|= [k=@ kl=@ t=@ tl=@]
=> .(k (end [3 kl] k), t (end [3 tl] t))
=+ b=64
=? k (gth kl b) (shay kl k)
=+ ^= q %+ shay (add b tl)
(add (lsh [3 b] t) (mix k (fil 3 b 0x36)))
%+ shay (add b 32)
(add (lsh [3 b] q) (mix k (fil 3 b 0x5c)))
:: :: ++pbk:scr:crypto
++ pbk :: PBKDF2-HMAC-SHA256
~/ %pbk
|= [p=@ s=@ c=@ d=@]
(pbl p (met 3 p) s (met 3 s) c d)
:: :: ++pbl:scr:crypto
++ pbl :: w+length
~/ %pbl
|= [p=@ pl=@ s=@ sl=@ c=@ d=@]
=> .(p (end [3 pl] p), s (end [3 sl] s))
=+ h=32
::
:: max key length 1GB
:: max iterations 2^28
::
?> ?& (lte d (bex 30))
(lte c (bex 28))
!=(c 0)
==
=+ ^= l ?~ (mod d h)
(div d h)
+((div d h))
=+ r=(sub d (mul h (dec l)))
=+ [t=0 j=1 k=1]
=. t |- ^- @
?: (gth j l) t
=+ u=(add s (lsh [3 sl] (rep 3 (flop (rpp 3 4 j)))))
=+ f=0 =. f |- ^- @
?: (gth k c) f
=+ q=(hml p pl u ?:(=(k 1) (add sl 4) h))
$(u q, f (mix f q), k +(k))
$(t (add t (lsh [3 (mul (dec j) h)] f)), j +(j))
(end [3 d] t)
:: :: ++hsh:scr:crypto
++ hsh :: scrypt
~/ %hsh
|= [p=@ s=@ n=@ r=@ z=@ d=@]
(hsl p (met 3 p) s (met 3 s) n r z d)
:: :: ++hsl:scr:crypto
++ hsl :: w+length
~/ %hsl
|= [p=@ pl=@ s=@ sl=@ n=@ r=@ z=@ d=@]
=| v=(list (list @))
=> .(p (end [3 pl] p), s (end [3 sl] s))
=+ u=(mul (mul 128 r) z)
::
:: n is power of 2; max 1GB memory
::
?> ?& =(n (bex (dec (xeb n))))
!=(r 0) !=(z 0)
%+ lte
(mul (mul 128 r) (dec (add n z)))
(bex 30)
(lth pl (bex 31))
(lth sl (bex 31))
==
=+ ^= b =+ (rpp 3 u (pbl p pl s sl 1 u))
%+ turn (bls (mul 128 r) -)
|=(a=(list @) (rpp 9 (mul 2 r) (rep 3 a)))
?> =((lent b) z)
=+ ^= q
=+ |- ?~ b (flop v)
$(b +.b, v [i=(srm r -.b n) t=v])
%+ turn `(list (list @))`-
|=(a=(list @) (rpp 3 (mul 128 r) (rep 9 a)))
(pbl p pl (rep 3 (slb q)) u 1 d)
:: :: ++ypt:scr:crypto
++ ypt :: 256bit {salt pass}
|= [s=@ p=@]
^- @
(hsh p s 16.384 8 1 256)
-- ::scr
:: ::
:::: ++crub:crypto :: (2b4) suite B, Ed
:: ::::
++ crub !:
^- acru
=| [pub=[cry=@ sgn=@] sek=(unit [cry=@ sgn=@])]
|%
:: :: ++as:crub:crypto
++ as ::
|%
:: :: ++sign:as:crub:
++ sign ::
|= msg=@
^- @ux
?~ sek ~| %pubkey-only !!
(jam [(sign:ed msg sgn.u.sek) msg])
:: :: ++sure:as:crub:
++ sure ::
|= txt=@
^- (unit @ux)
=+ ;;([sig=@ msg=@] (cue txt))
?. (veri:ed sig msg sgn.pub) ~
(some msg)
:: :: ++seal:as:crub:
++ seal ::
|= [bpk=pass msg=@]
^- @ux
?~ sek ~| %pubkey-only !!
?> =('b' (end 3 bpk))
=+ pk=(rsh 8 (rsh 3 bpk))
=+ shar=(shax (shar:ed pk cry.u.sek))
=+ smsg=(sign msg)
(jam (~(en siva:aes shar ~) smsg))
:: :: ++tear:as:crub:
++ tear ::
|= [bpk=pass txt=@]
^- (unit @ux)
?~ sek ~| %pubkey-only !!
?> =('b' (end 3 bpk))
=+ pk=(rsh 8 (rsh 3 bpk))
=+ shar=(shax (shar:ed pk cry.u.sek))
=+ ;;([iv=@ len=@ cph=@] (cue txt))
=+ try=(~(de siva:aes shar ~) iv len cph)
?~ try ~
(sure:as:(com:nu:crub bpk) u.try)
-- ::as
:: :: ++de:crub:crypto
++ de :: decrypt
|= [key=@J txt=@]
^- (unit @ux)
=+ ;;([iv=@ len=@ cph=@] (cue txt))
%^ ~(de sivc:aes (shaz key) ~)
iv
len
cph
:: :: ++dy:crub:crypto
++ dy :: need decrypt
|= [key=@J cph=@]
(need (de key cph))
:: :: ++en:crub:crypto
++ en :: encrypt
|= [key=@J msg=@]
^- @ux
(jam (~(en sivc:aes (shaz key) ~) msg))
:: :: ++ex:crub:crypto
++ ex :: extract
|%
:: :: ++fig:ex:crub:crypto
++ fig :: fingerprint
^- @uvH
(shaf %bfig pub)
:: :: ++pac:ex:crub:crypto
++ pac :: private fingerprint
^- @uvG
?~ sek ~| %pubkey-only !!
(end 6 (shaf %bcod sec))
:: :: ++pub:ex:crub:crypto
++ pub :: public key
^- pass
(cat 3 'b' (cat 8 sgn.^pub cry.^pub))
:: :: ++sec:ex:crub:crypto
++ sec :: private key
^- ring
?~ sek ~| %pubkey-only !!
(cat 3 'B' (cat 8 sgn.u.sek cry.u.sek))
-- ::ex
:: :: ++nu:crub:crypto
++ nu ::
|%
:: :: ++pit:nu:crub:crypto
++ pit :: create keypair
|= [w=@ seed=@]
=+ wid=(add (div w 8) ?:(=((mod w 8) 0) 0 1))
=+ bits=(shal wid seed)
=+ [c=(rsh 8 bits) s=(end 8 bits)]
..nu(pub [cry=(puck:ed c) sgn=(puck:ed s)], sek `[cry=c sgn=s])
:: :: ++nol:nu:crub:crypto
++ nol :: activate secret
|= a=ring
=+ [mag=(end 3 a) bod=(rsh 3 a)]
~| %not-crub-seckey ?> =('B' mag)
=+ [c=(rsh 8 bod) s=(end 8 bod)]
..nu(pub [cry=(puck:ed c) sgn=(puck:ed s)], sek `[cry=c sgn=s])
:: :: ++com:nu:crub:crypto
++ com :: activate public
|= a=pass
=+ [mag=(end 3 a) bod=(rsh 3 a)]
~| %not-crub-pubkey ?> =('b' mag)
..nu(pub [cry=(rsh 8 bod) sgn=(end 8 bod)], sek ~)
-- ::nu
-- ::crub
:: ::
:::: ++crua:crypto :: (2b5) suite B, RSA
:: ::::
++ crua !!
:: ::
:::: ++test:crypto :: (2b6) test crypto
:: ::::
++ test ^?
|%
:: :: ++trub:test:crypto
++ trub :: test crub
|= msg=@t
::
:: make acru cores
::
=/ ali (pit:nu:crub 512 (shaz 'Alice'))
=/ ali-pub (com:nu:crub pub:ex.ali)
=/ bob (pit:nu:crub 512 (shaz 'Robert'))
=/ bob-pub (com:nu:crub pub:ex.bob)
::
:: alice signs and encrypts a symmetric key to bob
::
=/ secret-key %- shaz
'Let there be no duplicity when taking a stand against him.'
=/ signed-key (sign:as.ali secret-key)
=/ crypted-key (seal:as.ali pub:ex.bob-pub signed-key)
:: bob decrypts and verifies
=/ decrypt-key-attempt (tear:as.bob pub:ex.ali-pub crypted-key)
=/ decrypted-key ~| %decrypt-fail (need decrypt-key-attempt)
=/ verify-key-attempt (sure:as.ali-pub decrypted-key)
=/ verified-key ~| %verify-fail (need verify-key-attempt)
:: bob encrypts with symmetric key
=/ crypted-msg (en.bob verified-key msg)
:: alice decrypts with same key
`@t`(dy.ali secret-key crypted-msg)
-- ::test
:: ::
:::: ++keccak:crypto :: (2b7) keccak family
:: ::::
++ keccak
~% %kecc ..part ~
|%
::
:: keccak
::
++ keccak-224 ~/ %k224 |=(a=octs (keccak 1.152 448 224 a))
++ keccak-256 ~/ %k256 |=(a=octs (keccak 1.088 512 256 a))
++ keccak-384 ~/ %k384 |=(a=octs (keccak 832 768 384 a))
++ keccak-512 ~/ %k512 |=(a=octs (keccak 576 1.024 512 a))
::
++ keccak (cury (cury hash keccak-f) padding-keccak)
::
++ padding-keccak (multirate-padding 0x1)
::
:: sha3
::
++ sha3-224 |=(a=octs (sha3 1.152 448 224 a))
++ sha3-256 |=(a=octs (sha3 1.088 512 256 a))
++ sha3-384 |=(a=octs (sha3 832 768 384 a))
++ sha3-512 |=(a=octs (sha3 576 1.024 512 a))
::
++ sha3 (cury (cury hash keccak-f) padding-sha3)
::
++ padding-sha3 (multirate-padding 0x6)
::
:: shake
::
++ shake-128 |=([o=@ud i=octs] (shake 1.344 256 o i))
++ shake-256 |=([o=@ud i=octs] (shake 1.088 512 o i))
::
++ shake (cury (cury hash keccak-f) padding-shake)
::
++ padding-shake (multirate-padding 0x1f)
::
:: rawshake
::
++ rawshake-128 |=([o=@ud i=octs] (rawshake 1.344 256 o i))
++ rawshake-256 |=([o=@ud i=octs] (rawshake 1.088 512 o i))
::
++ rawshake (cury (cury hash keccak-f) padding-rawshake)
::
++ padding-rawshake (multirate-padding 0x7)
::
:: core
::
++ hash
:: per: permutation function with configurable width.
:: pad: padding function.
:: rat: bitrate, size in bits of blocks to operate on.
:: cap: capacity, bits of sponge padding.
:: out: length of desired output, in bits.
:: inp: input to hash.
|= $: per=$-(@ud $-(@ @))
pad=$-([octs @ud] octs)
rat=@ud
cap=@ud
out=@ud
inp=octs
==
^- @
:: urbit's little-endian to keccak's big-endian.
=. q.inp (rev 3 inp)
%. [inp out]
(sponge per pad rat cap)
::
::NOTE if ++keccak ever needs to be made to operate
:: on bits rather than bytes, all that needs to
:: be done is updating the way this padding
:: function works. (and also "octs" -> "bits")
++ multirate-padding
:: dsb: domain separation byte, reverse bit order.
|= dsb=@ux
?> (lte dsb 0xff)
|= [inp=octs mut=@ud]
^- octs
=. mut (div mut 8)
=+ pal=(sub mut (mod p.inp mut))
=? pal =(pal 0) mut
=. pal (dec pal)
:- (add p.inp +(pal))
:: padding is provided in lane bit ordering,
:: ie, LSB = left.
(cat 3 (con (lsh [3 pal] dsb) 0x80) q.inp)
::
++ sponge
:: sponge construction
::
:: preperm: permutation function with configurable width.
:: padding: padding function.
:: bitrate: size of blocks to operate on.
:: capacity: sponge padding.
|= $: preperm=$-(@ud $-(@ @))
padding=$-([octs @ud] octs)
bitrate=@ud
capacity=@ud
==
::
:: preparing
=+ bitrate-bytes=(div bitrate 8)
=+ blockwidth=(add bitrate capacity)
=+ permute=(preperm blockwidth)
::
|= [input=octs output=@ud]
|^ ^- @
::
:: padding
=. input (padding input bitrate)
::
:: absorbing
=/ pieces=(list @)
:: amount of bitrate-sized blocks.
?> =(0 (mod p.input bitrate-bytes))
=+ i=(div p.input bitrate-bytes)
|-
?: =(i 0) ~
:_ $(i (dec i))
:: get the bitrate-sized block of bytes
:: that ends with the byte at -.
=- (cut 3 [- bitrate-bytes] q.input)
(mul (dec i) bitrate-bytes)
=/ state=@
:: for every piece,
%+ roll pieces
|= [p=@ s=@]
:: pad with capacity,
=. p (lsh [0 capacity] p)
:: xor it into the state and permute it.
(permute (mix s (bytes-to-lanes p)))
::
:: squeezing
=| res=@
=| len=@ud
|-
:: append a bitrate-sized head of state to the
:: result.
=. res
%+ con (lsh [0 bitrate] res)
(rsh [0 capacity] (lanes-to-bytes state))
=. len (add len bitrate)
?: (gte len output)
:: produce the requested bits of output.
(rsh [0 (sub len output)] res)
$(res res, state (permute state))
::
++ bytes-to-lanes
:: flip byte order in blocks of 8 bytes.
|= a=@
%^ run 6 a
|=(b=@ (lsh [3 (sub 8 (met 3 b))] (swp 3 b)))
::
++ lanes-to-bytes
:: unflip byte order in blocks of 8 bytes.
|= a=@
%+ can 6
%+ turn
=+ (rip 6 a)
(weld - (reap (sub 25 (lent -)) 0x0))
|= a=@
:- 1
%+ can 3
=- (turn - |=(a=@ [1 a]))
=+ (flop (rip 3 a))
(weld (reap (sub 8 (lent -)) 0x0) -)
--
::
++ keccak-f
:: keccak permutation function
|= [width=@ud]
:: assert valid blockwidth.
?> =- (~(has in -) width)
(sy 25 50 100 200 400 800 1.600 ~)
:: assumes 5x5 lanes state, as is the keccak
:: standard.
=+ size=5
=+ lanes=(mul size size)
=+ lane-bloq=(dec (xeb (div width lanes)))
=+ lane-size=(bex lane-bloq)
=+ rounds=(add 12 (mul 2 lane-bloq))
|= [input=@]
^- @
=* a input
=+ round=0
|^
?: =(round rounds) a
::
:: theta
=/ c=@
%+ roll (gulf 0 (dec size))
|= [x=@ud c=@]
%+ con (lsh [lane-bloq 1] c)
%+ roll (gulf 0 (dec size))
|= [y=@ud c=@]
(mix c (get-lane x y a))
=/ d=@
%+ roll (gulf 0 (dec size))
|= [x=@ud d=@]
%+ con (lsh [lane-bloq 1] d)
%+ mix
=- (get-word - size c)
?:(=(x 0) (dec size) (dec x))
%^ ~(rol fe lane-bloq) 0 1
(get-word (mod +(x) size) size c)
=. a
%+ roll (gulf 0 (dec lanes))
|= [i=@ud a=_a]
%+ mix a
%+ lsh
[lane-bloq (sub lanes +(i))]
(get-word i size d)
::
:: rho and pi
=/ b=@
%+ roll (gulf 0 (dec lanes))
|= [i=@ b=@]
=+ x=(mod i 5)
=+ y=(div i 5)
%+ con b
%+ lsh
:- lane-bloq
%+ sub lanes
%+ add +(y)
%+ mul size
(mod (add (mul 2 x) (mul 3 y)) size)
%^ ~(rol fe lane-bloq) 0
(rotation-offset i)
(get-word i lanes a)
::
:: chi
=. a
%+ roll (gulf 0 (dec lanes))
|= [i=@ud a=@]
%+ con (lsh lane-bloq a)
=+ x=(mod i 5)
=+ y=(div i 5)
%+ mix (get-lane x y b)
%+ dis
=- (get-lane - y b)
(mod (add x 2) size)
%^ not lane-bloq 1
(get-lane (mod +(x) size) y b)
::
:: iota
=. a
=+ (round-constant round)
(mix a (lsh [lane-bloq (dec lanes)] -))
::
:: next round
$(round +(round))
::
++ get-lane
:: get the lane with coordinates
|= [x=@ud y=@ud a=@]
=+ i=(add x (mul size y))
(get-word i lanes a)
::
++ get-word
:: get word {n} from atom {a} of {m} words.
|= [n=@ud m=@ud a=@]
(cut lane-bloq [(sub m +((mod n m))) 1] a)
::
++ round-constant
|= c=@ud
=- (snag (mod c 24) -)
^- (list @ux)
:~ 0x1
0x8082
0x8000.0000.0000.808a
0x8000.0000.8000.8000
0x808b
0x8000.0001
0x8000.0000.8000.8081
0x8000.0000.0000.8009
0x8a
0x88
0x8000.8009
0x8000.000a
0x8000.808b
0x8000.0000.0000.008b
0x8000.0000.0000.8089
0x8000.0000.0000.8003
0x8000.0000.0000.8002
0x8000.0000.0000.0080
0x800a
0x8000.0000.8000.000a
0x8000.0000.8000.8081
0x8000.0000.0000.8080
0x8000.0001
0x8000.0000.8000.8008
==
::
++ rotation-offset
|= x=@ud
=- (snag x -)
^- (list @ud)
:~ 0 1 62 28 27
36 44 6 55 20
3 10 43 25 39
41 45 15 21 8
18 2 61 56 14
==
--
-- ::keccak
:: ::
:::: ++hmac:crypto :: (2b8) hmac family
:: ::::
++ hmac
~% %hmac ..part ~
=, sha
=> |%
++ meet |=([k=@ m=@] [[(met 3 k) k] [(met 3 m) m]])
++ flip |=([k=@ m=@] [(swp 3 k) (swp 3 m)])
--
|%
::
:: use with @
::
++ hmac-sha1 (cork meet hmac-sha1l)
++ hmac-sha256 (cork meet hmac-sha256l)
++ hmac-sha512 (cork meet hmac-sha512l)
::
:: use with @t
::
++ hmac-sha1t (cork flip hmac-sha1)
++ hmac-sha256t (cork flip hmac-sha256)
++ hmac-sha512t (cork flip hmac-sha512)
::
:: use with byts
::
++ hmac-sha1l (cury hmac sha-1l 64 20)
++ hmac-sha256l (cury hmac sha-256l 64 32)
++ hmac-sha512l (cury hmac sha-512l 128 64)
::
:: main logic
::
++ hmac
~/ %hmac
:: boq: block size in bytes used by haj
:: out: bytes output by haj
|* [[haj=$-([@u @] @) boq=@u out=@u] key=byts msg=byts]
:: ensure key and message fit signaled lengths
=. dat.key (end [3 wid.key] dat.key)
=. dat.msg (end [3 wid.msg] dat.msg)
:: keys longer than block size are shortened by hashing
=? dat.key (gth wid.key boq) (haj wid.key dat.key)
=? wid.key (gth wid.key boq) out
:: keys shorter than block size are right-padded
=? dat.key (lth wid.key boq) (lsh [3 (sub boq wid.key)] dat.key)
:: pad key, inner and outer
=+ kip=(mix dat.key (fil 3 boq 0x36))
=+ kop=(mix dat.key (fil 3 boq 0x5c))
:: append inner padding to message, then hash
=+ (haj (add wid.msg boq) (add (lsh [3 wid.msg] kip) dat.msg))
:: prepend outer padding to result, hash again
(haj (add out boq) (add (lsh [3 out] kop) -))
-- :: hmac
:: ::
:::: ++secp:crypto :: (2b9) secp family
:: ::::
++ secp !.
:: TODO: as-octs and hmc are outside of jet parent
=> :+ ..part
hmc=hmac-sha256l:hmac:crypto
as-octs=as-octs:mimes:html
~% %secp +< ~
|%
+$ jacobian [x=@ y=@ z=@] :: jacobian point
+$ point [x=@ y=@] :: curve point
+$ domain
$: p=@ :: prime modulo
a=@ :: y^2=x^3+ax+b
b=@ ::
g=point :: base point
n=@ :: prime order of g
==
++ secp
|_ [bytes=@ =domain]
++ field-p ~(. fo p.domain)
++ field-n ~(. fo n.domain)
++ compress-point
|= =point
^- @
%+ can 3
:~ [bytes x.point]
[1 (add 2 (cut 0 [0 1] y.point))]
==
::
++ serialize-point
|= =point
^- @
%+ can 3
:~ [bytes y.point]
[bytes x.point]
[1 4]
==
::
++ decompress-point
|= compressed=@
^- point
=/ x=@ (end [3 bytes] compressed)
?> =(3 (mod p.domain 4))
=/ fop field-p
=+ [fadd fmul fpow]=[sum.fop pro.fop exp.fop]
=/ y=@ %+ fpow (rsh [0 2] +(p.domain))
%+ fadd b.domain
%+ fadd (fpow 3 x)
(fmul a.domain x)
=/ s=@ (rsh [3 bytes] compressed)
~| [`@ux`s `@ux`compressed]
?> |(=(2 s) =(3 s))
:: check parity
::
=? y !=((sub s 2) (mod y 2))
(sub p.domain y)
[x y]
::
++ jc :: jacobian math
|%
++ from
|= a=jacobian
^- point
=/ fop field-p
=+ [fmul fpow finv]=[pro.fop exp.fop inv.fop]
=/ z (finv z.a)
:- (fmul x.a (fpow 2 z))
(fmul y.a (fpow 3 z))
::
++ into
|= point
^- jacobian
[x y 1]
::
++ double
|= jacobian
^- jacobian
?: =(0 y) [0 0 0]
=/ fop field-p
=+ [fadd fsub fmul fpow]=[sum.fop dif.fop pro.fop exp.fop]
=/ s :(fmul 4 x (fpow 2 y))
=/ m %+ fadd
(fmul 3 (fpow 2 x))
(fmul a.domain (fpow 4 z))
=/ nx %+ fsub
(fpow 2 m)
(fmul 2 s)
=/ ny %+ fsub
(fmul m (fsub s nx))
(fmul 8 (fpow 4 y))
=/ nz :(fmul 2 y z)
[nx ny nz]
::
++ add
|= [a=jacobian b=jacobian]
^- jacobian
?: =(0 y.a) b
?: =(0 y.b) a
=/ fop field-p
=+ [fadd fsub fmul fpow]=[sum.fop dif.fop pro.fop exp.fop]
=/ u1 :(fmul x.a z.b z.b)
=/ u2 :(fmul x.b z.a z.a)
=/ s1 :(fmul y.a z.b z.b z.b)
=/ s2 :(fmul y.b z.a z.a z.a)
?: =(u1 u2)
?. =(s1 s2)
[0 0 1]
(double a)
=/ h (fsub u2 u1)
=/ r (fsub s2 s1)
=/ h2 (fmul h h)
=/ h3 (fmul h2 h)
=/ u1h2 (fmul u1 h2)
=/ nx %+ fsub
(fmul r r)
:(fadd h3 u1h2 u1h2)
=/ ny %+ fsub
(fmul r (fsub u1h2 nx))
(fmul s1 h3)
=/ nz :(fmul h z.a z.b)
[nx ny nz]
::
++ mul
|= [a=jacobian scalar=@]
^- jacobian
?: =(0 y.a)
[0 0 1]
?: =(0 scalar)
[0 0 1]
?: =(1 scalar)
a
?: (gte scalar n.domain)
$(scalar (mod scalar n.domain))
?: =(0 (mod scalar 2))
(double $(scalar (rsh 0 scalar)))
(add a (double $(scalar (rsh 0 scalar))))
--
++ add-points
|= [a=point b=point]
^- point
=/ j jc
(from.j (add.j (into.j a) (into.j b)))
++ mul-point-scalar
|= [p=point scalar=@]
^- point
=/ j jc
%- from.j
%+ mul.j
(into.j p)
scalar
::
++ valid-hash
|= has=@
(lte (met 3 has) bytes)
::
++ in-order
|= i=@
?& (gth i 0)
(lth i n.domain)
==
++ priv-to-pub
|= private-key=@
^- point
?> (in-order private-key)
(mul-point-scalar g.domain private-key)
::
++ make-k
|= [hash=@ private-key=@]
^- @
?> (in-order private-key)
?> (valid-hash hash)
=/ v (fil 3 bytes 1)
=/ k 0
=. k %+ hmc [bytes k]
%- as-octs
%+ can 3
:~ [bytes hash]
[bytes private-key]
[1 0]
[bytes v]
==
=. v (hmc bytes^k bytes^v)
=. k %+ hmc [bytes k]
%- as-octs
%+ can 3
:~ [bytes hash]
[bytes private-key]
[1 1]
[bytes v]
==
=. v (hmc bytes^k bytes^v)
(hmc bytes^k bytes^v)
::
++ ecdsa-raw-sign
|= [hash=@ private-key=@]
^- [r=@ s=@ y=@]
:: make-k and priv-to pub will validate inputs
=/ k (make-k hash private-key)
=/ rp (priv-to-pub k)
=* r x.rp
?< =(0 r)
=/ fon field-n
=+ [fadd fmul finv]=[sum.fon pro.fon inv.fon]
=/ s %+ fmul (finv k)
%+ fadd hash
%+ fmul r
private-key
?< =(0 s)
[r s y.rp]
:: general recovery omitted, but possible
--
++ secp256k1
~% %secp256k1 + ~
|%
++ t :: in the battery for jet matching
^- domain
:* 0xffff.ffff.ffff.ffff.ffff.ffff.ffff.ffff.
ffff.ffff.ffff.ffff.ffff.fffe.ffff.fc2f
0
7
:- 0x79be.667e.f9dc.bbac.55a0.6295.ce87.0b07.
029b.fcdb.2dce.28d9.59f2.815b.16f8.1798
0x483a.da77.26a3.c465.5da4.fbfc.0e11.08a8.
fd17.b448.a685.5419.9c47.d08f.fb10.d4b8
0xffff.ffff.ffff.ffff.ffff.ffff.ffff.fffe.
baae.dce6.af48.a03b.bfd2.5e8c.d036.4141
==
::
++ curve ~(. secp 32 t)
++ serialize-point serialize-point:curve
++ compress-point compress-point:curve
++ decompress-point decompress-point:curve
++ add-points add-points:curve
++ mul-point-scalar mul-point-scalar:curve
++ make-k
~/ %make
|= [hash=@uvI private-key=@]
:: checks sizes
(make-k:curve hash private-key)
++ priv-to-pub
|= private-key=@
:: checks sizes
(priv-to-pub:curve private-key)
::
++ ecdsa-raw-sign
~/ %sign
|= [hash=@uvI private-key=@]
^- [v=@ r=@ s=@]
=/ c curve
:: raw-sign checks sizes
=+ (ecdsa-raw-sign.c hash private-key)
=/ rp=point [r y]
=/ s-high (gte (mul 2 s) n.domain.c)
=? s s-high
(sub n.domain.c s)
=? rp s-high
[x.rp (sub p.domain.c y.rp)]
=/ v (end 0 y.rp)
=? v (gte x.rp n.domain.c)
(add v 2)
[v x.rp s]
::
++ ecdsa-raw-recover
~/ %reco
|= [hash=@ sig=[v=@ r=@ s=@]]
^- point
?> (lte v.sig 3)
=/ c curve
?> (valid-hash.c hash)
?> (in-order.c r.sig)
?> (in-order.c s.sig)
=/ x ?: (gte v.sig 2)
(add r.sig n.domain.c)
r.sig
=/ fop field-p.c
=+ [fadd fmul fpow]=[sum.fop pro.fop exp.fop]
=/ ysq (fadd (fpow 3 x) b.domain.c)
=/ beta (fpow (rsh [0 2] +(p.domain.c)) ysq)
=/ y ?: =((end 0 v.sig) (end 0 beta))
beta
(sub p.domain.c beta)
?> =(0 (dif.fop ysq (fmul y y)))
=/ nz (sub n.domain.c hash)
=/ j jc.c
=/ gz (mul.j (into.j g.domain.c) nz)
=/ xy (mul.j (into.j x y) s.sig)
=/ qr (add.j gz xy)
=/ qj (mul.j qr (inv:field-n.c x))
=/ pub (from.j qj)
?< =([0 0] pub)
pub
--
--
::
++ blake
~% %blake ..part ~
|%
::TODO generalize for both blake2 variants
++ blake2b
~/ %blake2b
|= [msg=byts key=byts out=@ud]
^- @
:: initialization vector
=/ iv=@
0x6a09.e667.f3bc.c908.
bb67.ae85.84ca.a73b.
3c6e.f372.fe94.f82b.
a54f.f53a.5f1d.36f1.
510e.527f.ade6.82d1.
9b05.688c.2b3e.6c1f.
1f83.d9ab.fb41.bd6b.
5be0.cd19.137e.2179
:: per-round constants
=/ sigma=(list (list @ud))
:~
:~ 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 ==
:~ 14 10 4 8 9 15 13 6 1 12 0 2 11 7 5 3 ==
:~ 11 8 12 0 5 2 15 13 10 14 3 6 7 1 9 4 ==
:~ 7 9 3 1 13 12 11 14 2 6 5 10 4 0 15 8 ==
:~ 9 0 5 7 2 4 10 15 14 1 11 12 6 8 3 13 ==
:~ 2 12 6 10 0 11 8 3 4 13 7 5 15 14 1 9 ==
:~ 12 5 1 15 14 13 4 10 0 7 6 3 9 2 8 11 ==
:~ 13 11 7 14 12 1 3 9 5 0 15 4 8 6 2 10 ==
:~ 6 15 14 9 11 3 0 8 12 2 13 7 1 4 10 5 ==
:~ 10 2 8 4 7 6 1 5 15 11 9 14 3 12 13 0 ==
:~ 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 ==
:~ 14 10 4 8 9 15 13 6 1 12 0 2 11 7 5 3 ==
==
=> |%
++ get-word-list
|= [h=@ w=@ud]
^- (list @)
%- flop
=+ l=(rip 6 h)
=- (weld - l)
(reap (sub w (lent l)) 0)
::
++ get-word
|= [h=@ i=@ud w=@ud]
^- @
%+ snag i
(get-word-list h w)
::
++ put-word
|= [h=@ i=@ud w=@ud d=@]
^- @
%+ rep 6
=+ l=(get-word-list h w)
%- flop
%+ weld (scag i l)
[d (slag +(i) l)]
::
++ mod-word
|* [h=@ i=@ud w=@ud g=$-(@ @)]
(put-word h i w (g (get-word h i w)))
::
++ pad
|= [byts len=@ud]
(lsh [3 (sub len wid)] dat)
::
++ compress
|= [h=@ c=@ t=@ud l=?]
^- @
:: set up local work vector
=+ v=(add (lsh [6 8] h) iv)
:: xor the counter t into v
=. v
%- mod-word
:^ v 12 16
(cury mix (end [0 64] t))
=. v
%- mod-word
:^ v 13 16
(cury mix (rsh [0 64] t))
:: for the last block, invert v14
=? v l
%- mod-word
:^ v 14 16
(cury mix 0xffff.ffff.ffff.ffff)
:: twelve rounds of message mixing
=+ i=0
=| s=(list @)
|^
?: =(i 12)
:: xor upper and lower halves of v into state h
=. h (mix h (rsh [6 8] v))
(mix h (end [6 8] v))
:: select message mixing schedule and mix v
=. s (snag (mod i 10) sigma)
=. v (do-mix 0 4 8 12 0 1)
=. v (do-mix 1 5 9 13 2 3)
=. v (do-mix 2 6 10 14 4 5)
=. v (do-mix 3 7 11 15 6 7)
=. v (do-mix 0 5 10 15 8 9)
=. v (do-mix 1 6 11 12 10 11)
=. v (do-mix 2 7 8 13 12 13)
=. v (do-mix 3 4 9 14 14 15)
$(i +(i))
::
++ do-mix
|= [na=@ nb=@ nc=@ nd=@ nx=@ ny=@]
^- @
=- =. v (put-word v na 16 a)
=. v (put-word v nb 16 b)
=. v (put-word v nc 16 c)
(put-word v nd 16 d)
%- b2mix
:* (get-word v na 16)
(get-word v nb 16)
(get-word v nc 16)
(get-word v nd 16)
(get-word c (snag nx s) 16)
(get-word c (snag ny s) 16)
==
--
::
++ b2mix
|= [a=@ b=@ c=@ d=@ x=@ y=@]
^- [a=@ b=@ c=@ d=@]
=. x (rev 3 8 x)
=. y (rev 3 8 y)
=+ fed=~(. fe 6)
=. a :(sum:fed a b x)
=. d (ror:fed 0 32 (mix d a))
=. c (sum:fed c d)
=. b (ror:fed 0 24 (mix b c))
=. a :(sum:fed a b y)
=. d (ror:fed 0 16 (mix d a))
=. c (sum:fed c d)
=. b (ror:fed 0 63 (mix b c))
[a b c d]
--
:: ensure inputs adhere to contraints
=. out (max 1 (min out 64))
=. wid.msg (min wid.msg (bex 128))
=. wid.key (min wid.key 64)
=. dat.msg (end [3 wid.msg] dat.msg)
=. dat.key (end [3 wid.key] dat.key)
:: initialize state vector
=+ h=iv
:: mix key length and output length into h0
=. h
%- mod-word
:^ h 0 8
%+ cury mix
%+ add 0x101.0000
(add (lsh 3 wid.key) out)
:: keep track of how much we've compressed
=* mes dat.msg
=+ com=0
=+ rem=wid.msg
:: if we have a key, pad it and prepend to msg
=? mes (gth wid.key 0)
(can 3 ~[rem^mes 128^(pad key 128)])
=? rem (gth wid.key 0)
(add rem 128)
|-
:: compress 128-byte chunks of the message
?: (gth rem 128)
=+ c=(cut 3 [(sub rem 128) 128] mes)
=. com (add com 128)
%_ $
rem (sub rem 128)
h (compress h c com |)
==
:: compress the final bytes of the msg
=+ c=(cut 3 [0 rem] mes)
=. com (add com rem)
=. c (pad [rem c] 128)
=. h (compress h c com &)
:: produce output of desired length
%+ rsh [3 (sub 64 out)]
:: do some word
%+ rep 6
%+ turn (flop (gulf 0 7))
|= a=@
(rev 3 8 (get-word h a 8))
-- ::blake
::
++ argon2
~% %argon ..part ~
|%
::
:: structures
::
+$ argon-type ?(%d %i %id %u)
::
:: shorthands
::
++ argon2-urbit
|= out=@ud
(argon2 out %u 0x13 4 512.000 1 *byts *byts)
::
:: argon2 proper
::
:: main argon2 operation
++ argon2
:: out: desired output size in bytes
:: typ: argon2 type
:: version: argon2 version (0x10/v1.0 or 0x13/v1.3)
:: threads: amount of threads/parallelism
:: mem-cost: kb of memory to use
:: time-cost: iterations to run
:: key: optional secret
:: extra: optional arbitrary data
|= $: out=@ud
typ=argon-type
version=@ux
::
threads=@ud
mem-cost=@ud
time-cost=@ud
::
key=byts
extra=byts
==
^- $-([msg=byts sat=byts] @)
::
:: check configuration sanity
::
?: =(0 threads)
~| %parallelism-must-be-above-zero
!!
?: =(0 time-cost)
~| %time-cost-must-be-above-zero
!!
?: (lth mem-cost (mul 8 threads))
~| :- %memory-cost-must-be-at-least-threads
[threads %times 8 (mul 8 threads)]
!!
?. |(=(0x10 version) =(0x13 version))
~| [%unsupported-version version %want [0x10 0x13]]
!!
::
:: calculate constants and initialize buffer
::
:: for each thread, there is a row in the buffer.
:: the amount of columns depends on the memory-cost.
:: columns are split into groups of four.
:: a single such quarter section of a row is a segment.
::
:: blocks: (m_prime)
:: columns: row length (q)
:: seg-length: segment length
=/ blocks=@ud
:: round mem-cost down to the nearest multiple of 4*threads
=+ (mul 4 threads)
(mul (div mem-cost -) -)
=+ columns=(div blocks threads)
=+ seg-length=(div columns 4)
::
=/ buffer=(list (list @))
(reap threads (reap columns 0))
::
:: main function
::
:: msg: the main input
:: sat: optional salt
~% %argon2 ..argon2 ~
|= [msg=byts sat=byts]
^- @
?: (lth wid.sat 8)
~| [%min-salt-length-is-8 wid.sat]
!!
::
:: h0: initial 64-byte block
=/ h0=@
=- (blake2b:blake - 0^0 64)
:- :(add 40 wid.msg wid.sat wid.key wid.extra)
%+ can 3
=+ (cury (cury rev 3) 4)
:~ (prep-wid extra)
(prep-wid key)
(prep-wid sat)
(prep-wid msg)
4^(- (type-to-num typ))
4^(- version)
4^(- time-cost)
4^(- mem-cost)
4^(- out)
4^(- threads)
==
::
:: do time-cost passes over the buffer
::
=+ t=0
|-
?: (lth t time-cost)
::
:: process all four segments in the columns...
::
=+ s=0
|-
?. (lth s 4) ^$(t +(t))
::
:: ...of every row/thread
::
=+ r=0
|-
?. (lth r threads) ^$(s +(s))
=; new=_buffer
$(buffer new, r +(r))
%- fill-segment
:* buffer h0
t s r
blocks columns seg-length
threads time-cost typ version
==
::
:: mix all rows together and hash the result
::
=+ r=0
=| final=@
|-
?: =(r threads)
(hash 1.024^final out)
=- $(final -, r +(r))
%+ mix final
(snag (dec columns) (snag r buffer))
::
:: per-segment computation
++ fill-segment
|= $: buffer=(list (list @))
h0=@
::
itn=@ud
seg=@ud
row=@ud
::
blocks=@ud
columns=@ud
seg-length=@ud
::
threads=@ud
time-cost=@ud
typ=argon-type
version=@ux
==
::
:: fill-segment utilities
::
=> |%
++ put-word
|= [rob=(list @) i=@ud d=@]
%+ weld (scag i rob)
[d (slag +(i) rob)]
--
^+ buffer
::
:: rob: row buffer to operate on
:: do-i: whether to use prns from input rather than state
:: rands: prns generated from input, if we do-i
=+ rob=(snag row buffer)
=/ do-i=?
?| ?=(%i typ)
&(?=(%id typ) =(0 itn) (lte seg 1))
&(?=(%u typ) =(0 itn) (lte seg 2))
==
=/ rands=(list (pair @ @))
?. do-i ~
::
:: keep going until we have a list of :seg-length prn pairs
::
=+ l=0
=+ counter=1
|- ^- (list (pair @ @))
?: (gte l seg-length) ~
=- (weld - $(counter +(counter), l (add l 128)))
::
:: generate pseudorandom block by compressing metadata
::
=/ random-block=@
%+ compress 0
%+ compress 0
%+ lsh [3 968]
%+ rep 6
=+ (cury (cury rev 3) 8)
:~ (- counter)
(- (type-to-num typ))
(- time-cost)
(- blocks)
(- seg)
(- row)
(- itn)
==
::
:: split the random-block into 64-bit sections,
:: then extract the first two 4-byte sections from each.
::
%+ turn (flop (rip 6 random-block))
|= a=@
^- (pair @ @)
:- (rev 3 4 (rsh 5 a))
(rev 3 4 (end 5 a))
::
:: iterate over the entire segment length
::
=+ sin=0
|-
::
:: when done, produce the updated buffer
::
?: =(sin seg-length)
%+ weld (scag row buffer)
[rob (slag +(row) buffer)]
::
:: col: current column to process
=/ col=@ud
(add (mul seg seg-length) sin)
::
:: first two columns are generated from h0
::
?: &(=(0 itn) (lth col 2))
=+ (app-num (app-num 64^h0 col) row)
=+ (hash - 1.024)
$(rob (put-word rob col -), sin +(sin))
::
:: c1, c2: prns for picking reference block
=/ [c1=@ c2=@]
?: do-i (snag sin rands)
=+ =- (snag - rob)
?: =(0 col) (dec columns)
(mod (dec col) columns)
:- (rev 3 4 (cut 3 [1.020 4] -))
(rev 3 4 (cut 3 [1.016 4] -))
::
:: ref-row: reference block row
=/ ref-row=@ud
?: &(=(0 itn) =(0 seg)) row
(mod c2 threads)
::
:: ref-col: reference block column
=/ ref-col=@ud
=- (mod - columns)
%+ add
:: starting index
?: |(=(0 itn) =(3 seg)) 0
(mul +(seg) seg-length)
:: pseudorandom offset
=- %+ sub (dec -)
%+ rsh [0 32]
%+ mul -
(rsh [0 32] (mul c1 c1))
:: reference area size
?: =(0 itn)
?: |(=(0 seg) =(row ref-row)) (dec col)
?: =(0 sin) (dec (mul seg seg-length))
(mul seg seg-length)
=+ sul=(sub columns seg-length)
?: =(ref-row row) (dec (add sul sin))
?: =(0 sin) (dec sul)
sul
::
:: compress the previous and reference block
:: to create the new block
::
=/ new=@
%+ compress
=- (snag - rob)
:: previous index, wrap-around
?: =(0 col) (dec columns)
(mod (dec col) columns)
:: get reference block
%+ snag ref-col
?: =(ref-row row) rob
(snag ref-row buffer)
::
:: starting from v1.3, we xor the new block in,
:: rather than directly overwriting the old block
::
=? new &(!=(0 itn) =(0x13 version))
(mix new (snag col rob))
$(rob (put-word rob col new), sin +(sin))
::
:: compression function (g)
++ compress
:: x, y: assumed to be 1024 bytes
|= [x=@ y=@]
^- @
::
=+ r=(mix x y)
=| q=(list @)
::
:: iterate over rows of r to get q
::
=+ i=0
|-
?: (lth i 8)
=; p=(list @)
$(q (weld q p), i +(i))
%- permute
=- (weld (reap (sub 8 (lent -)) 0) -)
%- flop
%+ rip 7
(cut 10 [(sub 7 i) 1] r)
::
:: iterate over columns of q to get z
::
=/ z=(list @) (reap 64 0)
=. i 0
|-
::
:: when done, assemble z and xor it with r
::
?. (lth i 8)
(mix (rep 7 (flop z)) r)
::
:: permute the column
::
=/ out=(list @)
%- permute
:~ (snag i q)
(snag (add i 8) q)
(snag (add i 16) q)
(snag (add i 24) q)
(snag (add i 32) q)
(snag (add i 40) q)
(snag (add i 48) q)
(snag (add i 56) q)
==
::
:: put the result into z per column
::
=+ j=0
|-
?: =(8 j) ^$(i +(i))
=- $(z -, j +(j))
=+ (add i (mul j 8))
%+ weld (scag - z)
[(snag j out) (slag +(-) z)]
::
:: permutation function (p)
++ permute
::NOTE this function really just takes and produces
:: 8 values, but taking and producing them as
:: lists helps clean up the code significantly.
|= s=(list @)
?> =(8 (lent s))
^- (list @)
::
:: list inputs as 16 8-byte values
::
=/ v=(list @)
%- zing
^- (list (list @))
%+ turn s
|= a=@
:: rev for endianness
=+ (rip 6 (rev 3 16 a))
(weld - (reap (sub 2 (lent -)) 0))
::
:: do permutation rounds
::
=. v (do-round v 0 4 8 12)
=. v (do-round v 1 5 9 13)
=. v (do-round v 2 6 10 14)
=. v (do-round v 3 7 11 15)
=. v (do-round v 0 5 10 15)
=. v (do-round v 1 6 11 12)
=. v (do-round v 2 7 8 13)
=. v (do-round v 3 4 9 14)
:: rev for endianness
=. v (turn v (cury (cury rev 3) 8))
::
:: cat v back together into 8 16-byte values
::
%+ turn (gulf 0 7)
|= i=@
=+ (mul 2 i)
(cat 6 (snag +(-) v) (snag - v))
::
:: perform a round and produce updated value list
++ do-round
|= [v=(list @) na=@ nb=@ nc=@ nd=@]
^+ v
=> |%
++ get-word
|= i=@ud
(snag i v)
::
++ put-word
|= [i=@ud d=@]
^+ v
%+ weld (scag i v)
[d (slag +(i) v)]
--
=- =. v (put-word na a)
=. v (put-word nb b)
=. v (put-word nc c)
(put-word nd d)
%- round
:* (get-word na)
(get-word nb)
(get-word nc)
(get-word nd)
==
::
:: perform a round (bg) and produce updated values
++ round
|= [a=@ b=@ c=@ d=@]
^- [a=@ b=@ c=@ d=@]
:: operate on 64 bit words
=+ fed=~(. fe 6)
=* sum sum:fed
=* ror ror:fed
=+ end=(cury end 5)
=. a :(sum a b :(mul 2 (end a) (end b)))
=. d (ror 0 32 (mix d a))
=. c :(sum c d :(mul 2 (end c) (end d)))
=. b (ror 0 24 (mix b c))
=. a :(sum a b :(mul 2 (end a) (end b)))
=. d (ror 0 16 (mix d a))
=. c :(sum c d :(mul 2 (end c) (end d)))
=. b (ror 0 63 (mix b c))
[a b c d]
::
:: argon2 wrapper around blake2b (h')
++ hash
=, blake
|= [byts out=@ud]
^- @
::
:: msg: input with byte-length prepended
=+ msg=(prep-num [wid dat] out)
::
:: if requested size is low enough, hash directly
::
?: (lte out 64)
(blake2b msg 0^0 out)
::
:: build up the result by hashing and re-hashing
:: the input message, adding the first 32 bytes
:: of the hash to the result, until we have the
:: desired output size.
::
=+ tmp=(blake2b msg 0^0 64)
=+ res=(rsh [3 32] tmp)
=. out (sub out 32)
|-
?: (gth out 64)
=. tmp (blake2b 64^tmp 0^0 64)
=. res (add (lsh [3 32] res) (rsh [3 32] tmp))
$(out (sub out 32))
%+ add (lsh [3 out] res)
(blake2b 64^tmp 0^0 out)
::
:: utilities
::
++ type-to-num
|= t=argon-type
?- t
%d 0
%i 1
%id 2
%u 10
==
::
++ app-num
|= [byts num=@ud]
^- byts
:- (add wid 4)
%+ can 3
~[4^(rev 3 4 num) wid^dat]
::
++ prep-num
|= [byts num=@ud]
^- byts
:- (add wid 4)
%+ can 3
~[wid^dat 4^(rev 3 4 num)]
::
++ prep-wid
|= a=byts
(prep-num a wid.a)
--
::
++ ripemd
~% %ripemd ..part ~
|%
++ ripemd-160
~/ %ripemd160
|= byts
^- @
:: we operate on bits rather than bytes
=. wid (mul wid 8)
:: add padding
=+ (md5-pad wid dat)
:: endianness
=. dat (run 5 dat |=(a=@ (rev 3 4 a)))
=* x dat
=+ blocks=(div wid 512)
=+ fev=~(. fe 5)
:: initial register values
=+ h0=0x6745.2301
=+ h1=0xefcd.ab89
=+ h2=0x98ba.dcfe
=+ h3=0x1032.5476
=+ h4=0xc3d2.e1f0
:: i: current block
=+ [i=0 j=0]
=+ *[a=@ b=@ c=@ d=@ e=@] :: a..e
=+ *[aa=@ bb=@ cc=@ dd=@ ee=@] :: a'..e'
|^
?: =(i blocks)
%+ rep 5
%+ turn `(list @)`~[h4 h3 h2 h1 h0]
:: endianness
|=(h=@ (rev 3 4 h))
=: a h0 aa h0
b h1 bb h1
c h2 cc h2
d h3 dd h3
e h4 ee h4
==
:: j: current word
=+ j=0
|-
?: =(j 80)
%= ^$
i +(i)
h1 :(sum:fev h2 d ee)
h2 :(sum:fev h3 e aa)
h3 :(sum:fev h4 a bb)
h4 :(sum:fev h0 b cc)
h0 :(sum:fev h1 c dd)
==
%= $
j +(j)
::
a e
b (fn j a b c d e (get (r j)) (k j) (s j))
c b
d (rol 10 c)
e d
::
aa ee
bb (fn (sub 79 j) aa bb cc dd ee (get (rr j)) (kk j) (ss j))
cc bb
dd (rol 10 cc)
ee dd
==
::
++ get :: word from x in block i
|= j=@ud
=+ (add (mul i 16) +(j))
(cut 5 [(sub (mul blocks 16) -) 1] x)
::
++ fn
|= [j=@ud a=@ b=@ c=@ d=@ e=@ m=@ k=@ s=@]
=- (sum:fev (rol s :(sum:fev a m k -)) e)
=. j (div j 16)
?: =(0 j) (mix (mix b c) d)
?: =(1 j) (con (dis b c) (dis (not 0 32 b) d))
?: =(2 j) (mix (con b (not 0 32 c)) d)
?: =(3 j) (con (dis b d) (dis c (not 0 32 d)))
?: =(4 j) (mix b (con c (not 0 32 d)))
!!
::
++ rol (cury rol:fev 0)
::
++ k
|= j=@ud
=. j (div j 16)
?: =(0 j) 0x0
?: =(1 j) 0x5a82.7999
?: =(2 j) 0x6ed9.eba1
?: =(3 j) 0x8f1b.bcdc
?: =(4 j) 0xa953.fd4e
!!
::
++ kk :: k'
|= j=@ud
=. j (div j 16)
?: =(0 j) 0x50a2.8be6
?: =(1 j) 0x5c4d.d124
?: =(2 j) 0x6d70.3ef3
?: =(3 j) 0x7a6d.76e9
?: =(4 j) 0x0
!!
::
++ r
|= j=@ud
%+ snag j
^- (list @)
:~ 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
7 4 13 1 10 6 15 3 12 0 9 5 2 14 11 8
3 10 14 4 9 15 8 1 2 7 0 6 13 11 5 12
1 9 11 10 0 8 12 4 13 3 7 15 14 5 6 2
4 0 5 9 7 12 2 10 14 1 3 8 11 6 15 13
==
::
++ rr :: r'
|= j=@ud
%+ snag j
^- (list @)
:~ 5 14 7 0 9 2 11 4 13 6 15 8 1 10 3 12
6 11 3 7 0 13 5 10 14 15 8 12 4 9 1 2
15 5 1 3 7 14 6 9 11 8 12 2 10 0 4 13
8 6 4 1 3 11 15 0 5 12 2 13 9 7 10 14
12 15 10 4 1 5 8 7 6 2 13 14 0 3 9 11
==
::
++ s
|= j=@ud
%+ snag j
^- (list @)
:~ 11 14 15 12 5 8 7 9 11 13 14 15 6 7 9 8
7 6 8 13 11 9 7 15 7 12 15 9 11 7 13 12
11 13 6 7 14 9 13 15 14 8 13 6 5 12 7 5
11 12 14 15 14 15 9 8 9 14 5 6 8 6 5 12
9 15 5 11 6 8 13 12 5 12 13 14 11 8 5 6
==
::
++ ss :: s'
|= j=@ud
%+ snag j
^- (list @)
:~ 8 9 9 11 13 15 15 5 7 7 8 11 14 14 12 6
9 13 15 7 12 8 9 11 7 7 12 7 6 15 13 11
9 7 15 11 8 6 6 14 12 13 5 14 13 13 7 5
15 5 8 11 14 14 6 14 6 9 12 9 12 5 15 8
8 5 12 9 12 5 14 6 8 13 6 5 15 13 11 11
==
--
::
++ md5-pad
|= byts
^- byts
=+ (sub 511 (mod (add wid 64) 512))
:- :(add 64 +(-) wid)
%+ can 0
~[64^(rev 3 8 wid) +(-)^(lsh [0 -] 1) wid^dat]
--
::
++ pbkdf
=> |%
++ meet |=([p=@ s=@ c=@ d=@] [[(met 3 p) p] [(met 3 s) s] c d])
++ flip |= [p=byts s=byts c=@ d=@]
[wid.p^(rev 3 p) wid.s^(rev 3 s) c d]
--
|%
::
:: use with @
::
++ hmac-sha1 (cork meet hmac-sha1l)
++ hmac-sha256 (cork meet hmac-sha256l)
++ hmac-sha512 (cork meet hmac-sha512l)
::
:: use with @t
::
++ hmac-sha1t (cork meet hmac-sha1d)
++ hmac-sha256t (cork meet hmac-sha256d)
++ hmac-sha512t (cork meet hmac-sha512d)
::
:: use with byts
::
++ hmac-sha1l (cork flip hmac-sha1d)
++ hmac-sha256l (cork flip hmac-sha256d)
++ hmac-sha512l (cork flip hmac-sha512d)
::
:: main logic
::
++ hmac-sha1d (cury pbkdf hmac-sha1l:hmac 20)
++ hmac-sha256d (cury pbkdf hmac-sha256l:hmac 32)
++ hmac-sha512d (cury pbkdf hmac-sha512l:hmac 64)
::
++ pbkdf
::TODO jet me! ++hmac:hmac is an example
|* [[prf=$-([byts byts] @) out=@u] p=byts s=byts c=@ d=@]
=> .(dat.p (end [3 wid.p] dat.p), dat.s (end [3 wid.s] dat.s))
::
:: max key length 1GB
:: max iterations 2^28
::
~| [%invalid-pbkdf-params c d]
?> ?& (lte d (bex 30))
(lte c (bex 28))
!=(c 0)
==
=/ l
?~ (mod d out)
(div d out)
+((div d out))
=+ r=(sub d (mul out (dec l)))
=+ [t=0 j=1 k=1]
=. t
|- ^- @
?: (gth j l) t
=/ u
%+ add dat.s
%+ lsh [3 wid.s]
%+ rep 3
(flop (rpp:scr 3 4 j))
=+ f=0
=. f
|- ^- @
?: (gth k c) f
=/ q
%^ rev 3 out
=+ ?:(=(k 1) (add wid.s 4) out)
(prf [wid.p (rev 3 p)] [- (rev 3 - u)])
$(u q, f (mix f q), k +(k))
$(t (add t (lsh [3 (mul (dec j) out)] f)), j +(j))
(rev 3 d (end [3 d] t))
--
-- ::crypto
:: ::::
:::: ++unity :: (2c) unit promotion
:: ::::
++ unity ^?
|%
:: :: ++drop-list:unity
++ drop-list :: collapse unit list
|* lut=(list (unit))
?. |- ^- ?
?~(lut & ?~(i.lut | $(lut t.lut)))
~
%- some
|-
?~ lut ~
[i=u:+.i.lut t=$(lut t.lut)]
:: :: ++drop-map:unity
++ drop-map :: collapse unit map
|* lum=(map term (unit))
?: (~(rep by lum) |=([[@ a=(unit)] b=_|] |(b ?=(~ a))))
~
(some (~(run by lum) need))
:: :: ++drop-pole:unity
++ drop-pole :: collapse to tuple
|^ |* pul=(pole (unit))
?: (test-pole pul) ~
(some (need-pole pul))
::
++ test-pole
|* pul=(pole (unit))
^- ?
?~ pul &
?| ?=(~ -.pul)
?~(+.pul | (test-pole +.pul))
==
::
++ need-pole
|* pul=(pole (unit))
?~ pul !!
?~ +.pul
u:->.pul
[u:->.pul (need-pole +.pul)]
--
--
:: ::::
:::: ++format :: (2d) common formats
:: ::::
++ format ^?
|%
:: 0 ending a line (invalid @t) is not preserved :: ++to-wain:format
++ to-wain :: cord to line list
~% %leer ..part ~
|= txt=cord
^- wain
=/ len=@ (met 3 txt)
=/ cut =+(cut -(a 3, c 1, d txt))
=/ sub sub
=| [i=@ out=wain]
|- ^+ out
=+ |- ^- j=@
?: ?| =(i len)
=(10 (cut(b i)))
==
i
$(i +(i))
=. out :_ out
(cut(b i, c (sub j i)))
?: =(j len)
(flop out)
$(i +(j))
:: :: ++of-wain:format
++ of-wain :: line list to cord
|= tez=wain ^- cord
(rap 3 (join '\0a' tez))
:: :: ++of-wall:format
++ of-wall :: line list to tape
|= a=wall ^- tape
?~(a ~ "{i.a}\0a{$(a t.a)}")
::
++ json-rn :: json to rn parser
%+ knee *rn |.
;~ plug
(easy %d)
;~(pose (cold | hep) (easy &))
;~ plug dim:ag
;~ pose
;~ pfix dot
%+ sear
|= a=tape
=/ b (rust a dum:ag)
?~ b ~
(some [(lent a) u.b])
(plus (shim '0' '9'))
==
(easy [0 0])
==
;~ pose
;~ pfix
(mask "eE")
;~ plug
;~(pose (cold | hep) (cold & lus) (easy &))
;~ pose
;~(pfix (plus (just '0')) dim:ag)
dim:ag
==
==
==
(easy [& 0])
==
==
==
:: :: ++enjs:format
++ enjs ^? :: json encoders
|%
:: :: ++frond:enjs:format
++ frond :: object from k-v pair
|= [p=@t q=json]
^- json
[%o [[p q] ~ ~]]
:: :: ++pairs:enjs:format
++ pairs :: object from k-v list
|= a=(list [p=@t q=json])
^- json
[%o (~(gas by *(map @t json)) a)]
:: :: ++tape:enjs:format
++ tape :: string from tape
|= a=^tape
^- json
[%s (crip a)]
:: :: ++wall:enjs:format
++ wall :: string from wall
|= a=^wall
^- json
(tape (of-wall a))
:: :: ++ship:enjs:format
++ ship :: string from ship
|= a=^ship
^- json
[%n (rap 3 '"' (rsh [3 1] (scot %p a)) '"' ~)]
:: :: ++numb:enjs:format
++ numb :: number from unsigned
|= a=@u
^- json
:- %n
?: =(0 a) '0'
%- crip
%- flop
|- ^- ^tape
?:(=(0 a) ~ [(add '0' (mod a 10)) $(a (div a 10))])
:: :: ++sect:enjs:format
++ sect :: s timestamp
|= a=^time
(numb (unt:chrono:userlib a))
:: :: ++time:enjs:format
++ time :: ms timestamp
|= a=^time
(numb (unm:chrono:userlib a))
:: :: ++path:enjs:format
++ path :: string from path
|= a=^path
^- json
[%s (spat a)]
:: :: ++tank:enjs:format
++ tank :: tank as string arr
|= a=^tank
^- json
[%a (turn (wash [0 80] a) tape)]
-- ::enjs
:: :: ++dejs:format
++ dejs :: json reparser
=> |% ++ grub * :: result
++ fist $-(json grub) :: reparser instance
-- ::
|%
:: :: ++ar:dejs:format
++ ar :: array as list
|* wit=fist
|= jon=json ^- (list _(wit *json))
?> ?=([%a *] jon)
(turn p.jon wit)
:: :: ++as:dejs:format
++ as :: array as set
|* a=fist
(cu ~(gas in *(set _$:a)) (ar a))
:: :: ++at:dejs:format
++ at :: array as tuple
|* wil=(pole fist)
|= jon=json
?> ?=([%a *] jon)
((at-raw wil) p.jon)
:: :: ++at-raw:dejs:format
++ at-raw :: array as tuple
|* wil=(pole fist)
|= jol=(list json)
?~ jol !!
?- wil :: mint-vain on empty
:: [wit=* t=*]
[* t=*]
=> .(wil [wit *]=wil)
?~ t.wil ?^(t.jol !! (wit.wil i.jol))
[(wit.wil i.jol) ((at-raw t.wil) t.jol)]
==
:: :: ++bo:dejs:format
++ bo :: boolean
|=(jon=json ?>(?=([%b *] jon) p.jon))
:: :: ++bu:dejs:format
++ bu :: boolean not
|=(jon=json ?>(?=([%b *] jon) !p.jon))
:: :: ++ci:dejs:format
++ ci :: maybe transform
|* [poq=gate wit=fist]
|= jon=json
(need (poq (wit jon)))
:: :: ++cu:dejs:format
++ cu :: transform
|* [poq=gate wit=fist]
|= jon=json
(poq (wit jon))
:: :: ++di:dejs:format
++ di :: millisecond date
(cu from-unix-ms:chrono:userlib ni)
:: :: ++du:dejs:format
++ du :: second date
(cu from-unix:chrono:userlib ni)
:: :: ++mu:dejs:format
++ mu :: true unit
|* wit=fist
|= jon=json
?~(jon ~ (some (wit jon)))
:: :: ++ne:dejs:format
++ ne :: number as real
|= jon=json
^- @rd
?> ?=([%n *] jon)
(rash p.jon (cook ryld (cook royl-cell:^so json-rn)))
:: :: ++ni:dejs:format
++ ni :: number as integer
|= jon=json
?> ?=([%n *] jon)
(rash p.jon dem)
:: :: ++no:dejs:format
++ no :: number as cord
|=(jon=json ?>(?=([%n *] jon) p.jon))
:: :: ++nu:dejs:format
++ nu :: parse number as hex
|= jon=json
?> ?=([%s *] jon)
(rash p.jon hex)
:: :: ++of:dejs:format
++ of :: object as frond
|* wer=(pole [cord fist])
|= jon=json
?> ?=([%o [@ *] ~ ~] jon)
|-
?- wer :: mint-vain on empty
:: [[key=@t wit=*] t=*]
[[key=@t *] t=*]
=> .(wer [[* wit] *]=wer)
?: =(key.wer p.n.p.jon)
[key.wer ~|(key+key.wer (wit.wer q.n.p.jon))]
?~ t.wer ~|(bad-key+p.n.p.jon !!)
((of t.wer) jon)
==
:: :: ++ot:dejs:format
++ ot :: object as tuple
|* wer=(pole [cord fist])
|= jon=json
?> ?=([%o *] jon)
((ot-raw wer) p.jon)
:: :: ++ot-raw:dejs:format
++ ot-raw :: object as tuple
|* wer=(pole [cord fist])
|= jom=(map @t json)
?- wer :: mint-vain on empty
:: [[key=@t wit=*] t=*]
[[key=@t *] t=*]
=> .(wer [[* wit] *]=wer)
=/ ten ~|(key+key.wer (wit.wer (~(got by jom) key.wer)))
?~(t.wer ten [ten ((ot-raw t.wer) jom)])
==
::
++ ou :: object of units
|* wer=(pole [cord fist])
|= jon=json
?> ?=([%o *] jon)
((ou-raw wer) p.jon)
:: :: ++ou-raw:dejs:format
++ ou-raw :: object of units
|* wer=(pole [cord fist])
|= jom=(map @t json)
?- wer :: mint-vain on empty
:: [[key=@t wit=*] t=*]
[[key=@t *] t=*]
=> .(wer [[* wit] *]=wer)
=/ ten ~|(key+key.wer (wit.wer (~(get by jom) key.wer)))
?~(t.wer ten [ten ((ou-raw t.wer) jom)])
==
:: :: ++oj:dejs:format
++ oj :: object as jug
|* =fist
^- $-(json (jug cord _(fist *json)))
(om (as fist))
:: :: ++om:dejs:format
++ om :: object as map
|* wit=fist
|= jon=json
?> ?=([%o *] jon)
(~(run by p.jon) wit)
:: :: ++op:dejs:format
++ op :: parse keys of map
|* [fel=rule wit=fist]
|= jon=json ^- (map _(wonk *fel) _*wit)
=/ jom ((om wit) jon)
%- malt
%+ turn ~(tap by jom)
|* [a=cord b=*]
=> .(+< [a b]=+<)
[(rash a fel) b]
:: :: ++pa:dejs:format
++ pa :: string as path
(su stap)
:: :: ++pe:dejs:format
++ pe :: prefix
|* [pre=* wit=fist]
(cu |*(* [pre +<]) wit)
:: :: ++sa:dejs:format
++ sa :: string as tape
|=(jon=json ?>(?=([%s *] jon) (trip p.jon)))
:: :: ++sd:dejs:format
++ sd :: string @ud as date
|= jon=json
^- @da
?> ?=(%s -.jon)
`@da`(rash p.jon dem:ag)
:: :: ++se:dejs:format
++ se :: string as aura
|= aur=@tas
|= jon=json
?>(?=([%s *] jon) (slav aur p.jon))
:: :: ++so:dejs:format
++ so :: string as cord
|=(jon=json ?>(?=([%s *] jon) p.jon))
:: :: ++su:dejs:format
++ su :: parse string
|* sab=rule
|= jon=json ^+ (wonk *sab)
?> ?=([%s *] jon)
(rash p.jon sab)
:: :: ++uf:dejs:format
++ uf :: unit fall
|* [def=* wit=fist]
|= jon=(unit json)
?~(jon def (wit u.jon))
:: :: ++un:dejs:format
++ un :: unit need
|* wit=fist
|= jon=(unit json)
(wit (need jon))
:: :: ++ul:dejs:format
++ ul :: null
|=(jon=json ?~(jon ~ !!))
::
++ za :: full unit pole
|* pod=(pole (unit))
?~ pod &
?~ -.pod |
(za +.pod)
::
++ zl :: collapse unit list
|* lut=(list (unit))
?. |- ^- ?
?~(lut & ?~(i.lut | $(lut t.lut)))
~
%- some
|-
?~ lut ~
[i=u:+.i.lut t=$(lut t.lut)]
::
++ zp :: unit tuple
|* but=(pole (unit))
?~ but !!
?~ +.but
u:->.but
[u:->.but (zp +.but)]
::
++ zm :: collapse unit map
|* lum=(map term (unit))
?: (~(rep by lum) |=([[@ a=(unit)] b=_|] |(b ?=(~ a))))
~
(some (~(run by lum) need))
-- ::dejs
:: :: ++dejs-soft:format
++ dejs-soft :: json reparse to unit
=, unity
=> |% ++ grub (unit *) :: result
++ fist $-(json grub) :: reparser instance
-- ::
::
:: XX: this is old code that replaced a rewritten dejs.
:: the rewritten dejs rest-looped with ++redo. the old
:: code is still in revision control -- revise and replace.
::
|%
++ ar :: array as list
|* wit=fist
|= jon=json
?. ?=([%a *] jon) ~
%- zl
|-
?~ p.jon ~
[i=(wit i.p.jon) t=$(p.jon t.p.jon)]
::
++ at :: array as tuple
|* wil=(pole fist)
|= jon=json
?. ?=([%a *] jon) ~
?. =((lent wil) (lent p.jon)) ~
=+ raw=((at-raw wil) p.jon)
?.((za raw) ~ (some (zp raw)))
::
++ at-raw :: array as tuple
|* wil=(pole fist)
|= jol=(list json)
?~ wil ~
:- ?~(jol ~ (-.wil i.jol))
((at-raw +.wil) ?~(jol ~ t.jol))
::
++ bo :: boolean
|=(jon=json ?.(?=([%b *] jon) ~ [~ u=p.jon]))
::
++ bu :: boolean not
|=(jon=json ?.(?=([%b *] jon) ~ [~ u=!p.jon]))
::
++ ci :: maybe transform
|* [poq=gate wit=fist]
|= jon=json
(biff (wit jon) poq)
::
++ cu :: transform
|* [poq=gate wit=fist]
|= jon=json
(bind (wit jon) poq)
::
++ da :: UTC date
|= jon=json
?. ?=([%s *] jon) ~
(bind (stud:chrono:userlib p.jon) |=(a=date (year a)))
::
++ dank :: tank
^- $-(json (unit tank))
%+ re *tank |. ~+
%- of :~
leaf+sa
palm+(ot style+(ot mid+sa cap+sa open+sa close+sa ~) lines+(ar dank) ~)
rose+(ot style+(ot mid+sa open+sa close+sa ~) lines+(ar dank) ~)
==
::
++ di :: millisecond date
(cu from-unix-ms:chrono:userlib ni)
::
++ mu :: true unit
|* wit=fist
|= jon=json
?~(jon (some ~) (bind (wit jon) some))
::
++ ne :: number as real
|= jon=json
^- (unit @rd)
?. ?=([%n *] jon) ~
(rush p.jon (cook ryld (cook royl-cell:^so json-rn)))
::
++ ni :: number as integer
|= jon=json
?. ?=([%n *] jon) ~
(rush p.jon dem)
::
++ no :: number as cord
|= jon=json
?. ?=([%n *] jon) ~
(some p.jon)
::
++ of :: object as frond
|* wer=(pole [cord fist])
|= jon=json
?. ?=([%o [@ *] ~ ~] jon) ~
|-
?~ wer ~
?: =(-.-.wer p.n.p.jon)
((pe -.-.wer +.-.wer) q.n.p.jon)
((of +.wer) jon)
::
++ ot :: object as tuple
|* wer=(pole [cord fist])
|= jon=json
?. ?=([%o *] jon) ~
=+ raw=((ot-raw wer) p.jon)
?.((za raw) ~ (some (zp raw)))
::
++ ot-raw :: object as tuple
|* wer=(pole [cord fist])
|= jom=(map @t json)
?~ wer ~
=+ ten=(~(get by jom) -.-.wer)
[?~(ten ~ (+.-.wer u.ten)) ((ot-raw +.wer) jom)]
::
++ om :: object as map
|* wit=fist
|= jon=json
?. ?=([%o *] jon) ~
(zm (~(run by p.jon) wit))
::
++ op :: parse keys of map
|* [fel=rule wit=fist]
%+ cu
|= a=(list (pair _(wonk *fel) _(need *wit)))
(my:nl a)
%- ci :_ (om wit)
|= a=(map cord _(need *wit))
^- (unit (list _[(wonk *fel) (need *wit)]))
%- zl
%+ turn ~(tap by a)
|= [a=cord b=_(need *wit)]
=+ nit=(rush a fel)
?~ nit ~
(some [u.nit b])
::
++ pe :: prefix
|* [pre=* wit=fist]
(cu |*(* [pre +<]) wit)
::
++ re :: recursive reparsers
|* [gar=* sef=_|.(fist)]
|= jon=json
^- (unit _gar)
((sef) jon)
::
++ sa :: string as tape
|= jon=json
?.(?=([%s *] jon) ~ (some (trip p.jon)))
::
++ so :: string as cord
|= jon=json
?.(?=([%s *] jon) ~ (some p.jon))
::
++ su :: parse string
|* sab=rule
|= jon=json
?. ?=([%s *] jon) ~
(rush p.jon sab)
::
++ ul |=(jon=json ?~(jon (some ~) ~)) :: null
++ za :: full unit pole
|* pod=(pole (unit))
?~ pod &
?~ -.pod |
(za +.pod)
::
++ zl :: collapse unit list
|* lut=(list (unit))
?. |- ^- ?
?~(lut & ?~(i.lut | $(lut t.lut)))
~
%- some
|-
?~ lut ~
[i=u:+.i.lut t=$(lut t.lut)]
::
++ zp :: unit tuple
|* but=(pole (unit))
?~ but !!
?~ +.but
u:->.but
[u:->.but (zp +.but)]
::
++ zm :: collapse unit map
|* lum=(map term (unit))
?: (~(rep by lum) |=([[@ a=(unit)] b=_|] |(b ?=(~ a))))
~
(some (~(run by lum) need))
-- ::dejs-soft
--
:: |cloy: clay helpers
::
++ cloy
=, clay
|%
++ new-desk
|= [=desk tako=(unit tako) files=(map path page)]
[%c %park desk &/[(drop tako) (~(run by files) (lead %&))] *rang]
:: +an: $ankh interface door
::
++ an
|_ nak=ankh
:: +dug: produce ankh at path
::
++ dug
|= =path
^- (unit ankh)
?~ path `nak
?~ kid=(~(get by dir.nak) i.path)
~
$(nak u.kid, path t.path)
:: +get: produce file at path
::
++ get
|= =path
^- (unit cage)
?~ nik=(dug path) ~
?~ fil.u.nik ~
`q.u.fil.u.nik
:: +mup: convert sub-tree at .pre to (map path [lobe cage])
::
++ mup
|= pre=path
=- ~? =(~ -) [%oh-no-empty pre]
-
^- (map path [lobe cage])
=/ nek=(unit ankh) (dug pre)
?~ nek
~& [%oh-no-empty-pre pre ~(key by dir.nak)]
~
=. nak u.nek
~? =(~ nak) [%oh-no-empty-nak pre]
=| pax=path
=| res=(map path [=lobe =cage])
|- ^+ res
=? res ?=(^ fil.nak) (~(put by res) pax u.fil.nak)
:: =/ anz=(list [seg=@ta =ankh]) ~(tap by dir.nak)
:: |- ^+ res
:: ?~ anz res
:: %_ $
:: anz t.anz
:: res ^$(pax (snoc pax seg.i.anz), nak ankh.i.anz)
:: ==
%+ roll ~(tap by dir.nak)
|= [[seg=@ta =ankh] res=_res]
^$(pax (snoc pax seg), nak ankh, res res)
--
--
:: ::
:::: ++differ :: (2d) hunt-mcilroy
:: ::::
++ differ ^?
=, clay
=, format
|%
:: :: ++berk:differ
++ berk :: invert diff patch
|* bur=(urge)
|- ^+ bur
?~ bur ~
:_ $(bur t.bur)
?- -.i.bur
%& i.bur
%| [%| q.i.bur p.i.bur]
==
:: :: ++loss:differ
++ loss :: longest subsequence
~% %loss ..part ~
|* [hel=(list) hev=(list)]
|- ^+ hev
=+ ^= sev
=+ [inx=0 sev=*(map _i.-.hev (list @ud))]
|- ^+ sev
?~ hev sev
=+ guy=(~(get by sev) i.hev)
%= $
hev t.hev
inx +(inx)
sev (~(put by sev) i.hev [inx ?~(guy ~ u.guy)])
==
=| gox=[p=@ud q=(map @ud [p=@ud q=_hev])]
=< abet
=< main
|%
:: :: ++abet:loss:differ
++ abet :: subsequence
^+ hev
?: =(0 p.gox) ~
(flop q:(need (~(get by q.gox) (dec p.gox))))
:: :: ++hink:loss:differ
++ hink :: extend fits top
|= [inx=@ud goy=@ud] ^- ?
?| =(p.gox inx)
(lth goy p:(need (~(get by q.gox) inx)))
==
:: :: ++lonk:loss:differ
++ lonk :: extend fits bottom
|= [inx=@ud goy=@ud] ^- ?
?| =(0 inx)
(gth goy p:(need (~(get by q.gox) (dec inx))))
==
:: :: ++luna:loss:differ
++ luna :: extend
|= [inx=@ud goy=@ud]
^+ +>
%_ +>.$
gox
:- ?:(=(inx p.gox) +(p.gox) p.gox)
%+ ~(put by q.gox) inx
:+ goy
(snag goy hev)
?:(=(0 inx) ~ q:(need (~(get by q.gox) (dec inx))))
==
:: :: ++merg:loss:differ
++ merg :: merge all matches
|= gay=(list @ud)
^+ +>
=+ ^= zes
=+ [inx=0 zes=*(list [p=@ud q=@ud])]
|- ^+ zes
?: |(?=(~ gay) (gth inx p.gox)) zes
?. (lonk inx i.gay) $(gay t.gay)
?. (hink inx i.gay) $(inx +(inx))
$(inx +(inx), gay t.gay, zes [[inx i.gay] zes])
|- ^+ +>.^$
?~(zes +>.^$ $(zes t.zes, +>.^$ (luna i.zes)))
:: :: ++main:loss:differ
++ main ::
=+ hol=hel
|- ^+ +>
?~ hol +>
=+ guy=(~(get by sev) i.hol)
$(hol t.hol, +> (merg (flop `(list @ud)`?~(guy ~ u.guy))))
-- ::
:: :: ++lurk:differ
++ lurk :: apply list patch
|* [hel=(list) rug=(urge)]
^+ hel
=+ war=`_hel`~
|- ^+ hel
?~ rug (flop war)
?- -.i.rug
%&
%= $
rug t.rug
hel (slag p.i.rug hel)
war (weld (flop (scag p.i.rug hel)) war)
==
::
%|
%= $
rug t.rug
hel =+ gur=(flop p.i.rug)
|- ^+ hel
?~ gur hel
?>(&(?=(^ hel) =(i.gur i.hel)) $(hel t.hel, gur t.gur))
war (weld q.i.rug war)
==
==
:: :: ++lusk:differ
++ lusk :: lcs to list patch
|* [hel=(list) hev=(list) lcs=(list)]
=+ ^= rag
^- [$%([%& p=@ud] [%| p=_lcs q=_lcs])]
[%& 0]
=> .(rag [p=rag q=*(list _rag)])
=< abet =< main
|%
:: :: ++abet:lusk:differ
++ abet ::
=? q.rag !=([& 0] p.rag) [p.rag q.rag]
(flop q.rag)
:: :: ++done:lusk:differ
++ done ::
|= new=_p.rag
^+ rag
?- -.p.rag
%| ?- -.new
%| [[%| (weld p.new p.p.rag) (weld q.new q.p.rag)] q.rag]
%& [new [p.rag q.rag]]
==
%& ?- -.new
%| [new ?:(=(0 p.p.rag) q.rag [p.rag q.rag])]
%& [[%& (add p.p.rag p.new)] q.rag]
==
==
:: :: ++main:lusk:differ
++ main ::
|- ^+ +
?~ hel
?~ hev
?>(?=(~ lcs) +)
$(hev t.hev, rag (done %| ~ [i.hev ~]))
?~ hev
$(hel t.hel, rag (done %| [i.hel ~] ~))
?~ lcs
+(rag (done %| (flop hel) (flop hev)))
?: =(i.hel i.lcs)
?: =(i.hev i.lcs)
$(lcs t.lcs, hel t.hel, hev t.hev, rag (done %& 1))
$(hev t.hev, rag (done %| ~ [i.hev ~]))
?: =(i.hev i.lcs)
$(hel t.hel, rag (done %| [i.hel ~] ~))
$(hel t.hel, hev t.hev, rag (done %| [i.hel ~] [i.hev ~]))
-- ::
-- ::differ
:: ::
:::: ++html :: (2e) text encodings
:: ::::
++ html ^? :: XX rename to web-txt
=, eyre
|%
:: ::
:::: ++mimes:html :: (2e1) MIME
:: ::::
++ mimes ^?
~% %mimes ..part ~
|%
:: :: ++as-octs:mimes:html
++ as-octs :: atom to octstream
|= tam=@ ^- octs
[(met 3 tam) tam]
:: :: ++as-octt:mimes:html
++ as-octt :: tape to octstream
|= tep=tape ^- octs
(as-octs (rap 3 tep))
:: :: ++en-mite:mimes:html
++ en-mite :: mime type to text
|= myn=mite
%- crip
|- ^- tape
?~ myn ~
?: =(~ t.myn) (trip i.myn)
(weld (trip i.myn) `tape`['/' $(myn t.myn)])
::
:: |base16: en/decode arbitrary MSB-first hex strings
::
++ base16
~% %base16 + ~
|%
++ en
~/ %en
|= a=octs ^- cord
(crip ((x-co:co (mul p.a 2)) (end [3 p.a] q.a)))
::
++ de
~/ %de
|= a=cord ^- (unit octs)
(rush a rule)
::
++ rule
%+ cook
|= a=(list @) ^- octs
[(add (dvr (lent a) 2)) (rep [0 4] (flop a))]
(star hit)
--
:: |base64: flexible base64 encoding for little-endian atoms
::
++ base64
=> |%
+$ byte @D
+$ word24 @
::
++ div-ceil
:: divide, rounding up.
|= [x=@ y=@] ^- @
?: =(0 (mod x y))
(div x y)
+((div x y))
::
++ explode-bytes
:: Explode a bytestring into list of bytes. Result is in LSB order.
|= =octs ^- (list byte)
=/ atom-byte-width (met 3 q.octs)
=/ leading-zeros (sub p.octs atom-byte-width)
(weld (reap leading-zeros 0) (rip 3 q.octs))
::
++ explode-words
:: Explode a bytestring to words of bit-width `wid`. Result is in LSW order.
|= [wid=@ =octs]
^- (list @)
=/ atom-bit-width (met 0 q.octs)
=/ octs-bit-width (mul 8 p.octs)
=/ atom-word-width (div-ceil atom-bit-width wid)
=/ rslt-word-width (div-ceil octs-bit-width wid)
=/ pad (sub rslt-word-width atom-word-width)
=/ x (rip [0 wid] q.octs)
%+ weld x
(reap pad 0)
--
::
:: pad: include padding when encoding, require when decoding
:: url: use url-safe characters '-' for '+' and '_' for '/'
::
=+ [pad=& url=|]
|%
:: +en:base64: encode +octs to base64 cord
::
:: Encode an `octs` into a base64 string.
::
:: First, we break up the input into a list of 24-bit words. The input
:: might not be a multiple of 24-bits, so we add 0-2 padding bytes at
:: the end (to the least-significant side, with a left-shift).
::
:: Then, we encode each block into four base64 characters.
::
:: Finally we remove the padding that we added at the beginning: for
:: each byte that was added, we replace one character with an = (unless
:: `pad` is false, in which case we just remove the extra characters).
::
++ en
^- $-(octs cord)
::
=/ cha
?: url
'ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789-_'
'ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/'
::
|^ |= bs=octs ^- cord
=/ [padding=@ blocks=(list word24)]
(octs-to-blocks bs)
(crip (flop (unpad padding (encode-blocks blocks))))
::
++ octs-to-blocks
|= bs=octs ^- [padding=@ud (list word24)]
=/ padding=@ud (~(dif fo 3) 0 p.bs)
=/ padded=octs [(add padding p.bs) (lsh [3 padding] (rev 3 bs))]
[padding (explode-words 24 padded)]
::
++ unpad
|= [extra=@ t=tape] ^- tape
=/ without (slag extra t)
?. pad without
(weld (reap extra '=') without)
::
++ encode-blocks
|= ws=(list word24) ^- tape
(zing (turn ws encode-block))
::
++ encode-block
|= w=word24 ^- tape
=/ a (cut 3 [(cut 0 [0 6] w) 1] cha)
=/ b (cut 3 [(cut 0 [6 6] w) 1] cha)
=/ c (cut 3 [(cut 0 [12 6] w) 1] cha)
=/ d (cut 3 [(cut 0 [18 6] w) 1] cha)
~[a b c d]
--
::
:: +de:base64: decode base64 cord to (unit @)
::
++ de
|= a=cord
^- (unit octs)
(rush a parse)
:: +parse:base64: parse base64 cord to +octs
::
++ parse
=< ^- $-(nail (like octs))
%+ sear reduce
;~ plug
%- plus ;~ pose
(cook |=(a=@ (sub a 'A')) (shim 'A' 'Z'))
(cook |=(a=@ (sub a 'G')) (shim 'a' 'z'))
(cook |=(a=@ (add a 4)) (shim '0' '9'))
(cold 62 (just ?:(url '-' '+')))
(cold 63 (just ?:(url '_' '/')))
==
(stun 0^2 (cold %0 tis))
==
|%
:: +reduce:parse:base64: reduce, measure, and swap base64 digits
::
++ reduce
|= [dat=(list @) dap=(list @)]
^- (unit octs)
=/ lat (lent dat)
=/ lap (lent dap)
=/ dif (~(dif fo 4) 0 lat)
?: &(pad !=(dif lap))
:: padding required and incorrect
~&(%base-64-padding-err-one ~)
?: &(!pad !=(0 lap))
:: padding not required but present
~&(%base-64-padding-err-two ~)
=/ len (sub (mul 3 (div (add lat dif) 4)) dif)
:+ ~ len
%+ swp 3
(rep [0 6] (flop (weld dat (reap dif 0))))
--
--
::
++ en-base58
|= dat=@
=/ cha
'123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz'
%- flop
|- ^- tape
?: =(0 dat) ~
:- (cut 3 [(mod dat 58) 1] cha)
$(dat (div dat 58))
::
++ de-base58
|= t=tape
=- (scan t (bass 58 (plus -)))
;~ pose
(cook |=(a=@ (sub a 56)) (shim 'A' 'H'))
(cook |=(a=@ (sub a 57)) (shim 'J' 'N'))
(cook |=(a=@ (sub a 58)) (shim 'P' 'Z'))
(cook |=(a=@ (sub a 64)) (shim 'a' 'k'))
(cook |=(a=@ (sub a 65)) (shim 'm' 'z'))
(cook |=(a=@ (sub a 49)) (shim '1' '9'))
==
-- ::mimes
:: :: ++en-json:html
++ en-json :: print json
|^ |=(val=json (apex val ""))
:: :: ++apex:en-json:html
++ apex
|= [val=json rez=tape]
^- tape
?~ val (weld "null" rez)
?- -.val
%a
:- '['
=. rez [']' rez]
!.
?~ p.val rez
|-
?~ t.p.val ^$(val i.p.val)
^$(val i.p.val, rez [',' $(p.val t.p.val)])
::
%b (weld ?:(p.val "true" "false") rez)
%n (weld (trip p.val) rez)
%s
:- '"'
=. rez ['"' rez]
=+ viz=(trip p.val)
!.
|- ^- tape
?~ viz rez
=+ hed=(jesc i.viz)
?: ?=([@ ~] hed)
[i.hed $(viz t.viz)]
(weld hed $(viz t.viz))
::
%o
:- '{'
=. rez ['}' rez]
=+ viz=~(tap by p.val)
?~ viz rez
!.
|- ^+ rez
?~ t.viz ^$(val [%s p.i.viz], rez [':' ^$(val q.i.viz)])
=. rez [',' $(viz t.viz)]
^$(val [%s p.i.viz], rez [':' ^$(val q.i.viz)])
==
:: :: ++jesc:en-json:html
++ jesc :: escaped
=+ utf=|=(a=@ ['\\' 'u' ((x-co 4):co a)])
|= a=@ ^- tape
?+ a ?:((gth a 0x1f) [a ~] (utf a))
%10 "\\n"
%34 "\\\""
%92 "\\\\"
==
-- ::en-json
:: :: ++de-json:html
++ de-json :: parse JSON
=< |=(a=cord `(unit json)`(rush a apex))
|%
:: :: ++abox:de-json:html
++ abox :: array
%+ stag %a
(ifix [sel (wish ser)] (more (wish com) apex))
:: :: ++apex:de-json:html
++ apex :: any value
%+ knee *json |. ~+
%+ ifix [spac spac]
;~ pose
(cold ~ (jest 'null'))
(stag %b bool)
(stag %s stri)
(cook |=(s=tape [%n p=(rap 3 s)]) numb)
abox
obox
==
:: :: ++bool:de-json:html
++ bool :: boolean
;~ pose
(cold & (jest 'true'))
(cold | (jest 'false'))
==
:: :: ++digs:de-json:html
++ digs :: digits
(star (shim '0' '9'))
:: :: ++esca:de-json:html
++ esca :: escaped character
;~ pfix bas
=* loo
=* lip
^- (list (pair @t @))
[b+8 t+9 n+10 f+12 r+13 ~]
=* wow `(map @t @)`(malt lip)
(sear ~(get by wow) low)
=* tuf ;~(pfix (just 'u') (cook tuft qix:ab))
;~(pose doq fas soq bas loo tuf)
==
:: :: ++expo:de-json:html
++ expo :: exponent
;~ (comp twel)
(piec (mask "eE"))
(mayb (piec (mask "+-")))
digs
==
:: :: ++frac:de-json:html
++ frac :: fraction
;~(plug dot digs)
:: :: ++jcha:de-json:html
++ jcha :: string character
;~(pose ;~(less doq bas prn) esca)
:: :: ++mayb:de-json:html
++ mayb :: optional
|*(bus=rule ;~(pose bus (easy ~)))
:: :: ++numb:de-json:html
++ numb :: number
;~ (comp twel)
(mayb (piec hep))
;~ pose
(piec (just '0'))
;~(plug (shim '1' '9') digs)
==
(mayb frac)
(mayb expo)
==
:: :: ++obje:de-json:html
++ obje :: object list
%+ ifix [(wish kel) (wish ker)]
(more (wish com) pear)
:: :: ++obox:de-json:html
++ obox :: object
(stag %o (cook malt obje))
:: :: ++pear:de-json:html
++ pear :: key-value
;~(plug ;~(sfix (wish stri) (wish col)) apex)
:: :: ++piec:de-json:html
++ piec :: listify
|* bus=rule
(cook |=(a=@ [a ~]) bus)
:: :: ++stri:de-json:html
++ stri :: string
(cook crip (ifix [doq doq] (star jcha)))
:: :: ++tops:de-json:html
++ tops :: strict value
;~(pose abox obox)
:: :: ++spac:de-json:html
++ spac :: whitespace
(star (mask [`@`9 `@`10 `@`13 ' ' ~]))
:: :: ++twel:de-json:html
++ twel :: tape weld
|=([a=tape b=tape] (weld a b))
:: :: ++wish:de-json:html
++ wish :: with whitespace
|*(sef=rule ;~(pfix spac sef))
-- ::de-json
:: :: ++en-xml:html
++ en-xml :: xml printer
=< |=(a=manx `tape`(apex a ~))
|_ _[unq=`?`| cot=`?`|]
:: :: ++apex:en-xml:html
++ apex :: top level
|= [mex=manx rez=tape]
^- tape
?: ?=([%$ [[%$ *] ~]] g.mex)
(escp v.i.a.g.mex rez)
=+ man=`mane`n.g.mex
=. unq |(unq =(%script man) =(%style man))
=+ tam=(name man)
=+ att=`mart`a.g.mex
:- '<'
%+ welp tam
=- ?~(att rez [' ' (attr att rez)])
^- rez=tape
?: &(?=(~ c.mex) |(cot ?^(man | (clot man))))
[' ' '/' '>' rez]
:- '>'
(many c.mex :(weld "</" tam ">" rez))
:: :: ++attr:en-xml:html
++ attr :: attributes to tape
|= [tat=mart rez=tape]
^- tape
?~ tat rez
=. rez $(tat t.tat)
;: weld
(name n.i.tat)
"=\""
(escp(unq |) v.i.tat '"' ?~(t.tat rez [' ' rez]))
==
:: :: ++escp:en-xml:html
++ escp :: escape for xml
|= [tex=tape rez=tape]
?: unq
(weld tex rez)
=+ xet=`tape`(flop tex)
!.
|- ^- tape
?~ xet rez
%= $
xet t.xet
rez ?- i.xet
%34 ['&' 'q' 'u' 'o' 't' ';' rez]
%38 ['&' 'a' 'm' 'p' ';' rez]
%39 ['&' '#' '3' '9' ';' rez]
%60 ['&' 'l' 't' ';' rez]
%62 ['&' 'g' 't' ';' rez]
* [i.xet rez]
==
==
:: :: ++many:en-xml:html
++ many :: nodelist to tape
|= [lix=(list manx) rez=tape]
|- ^- tape
?~ lix rez
(apex i.lix $(lix t.lix))
:: :: ++name:en-xml:html
++ name :: name to tape
|= man=mane ^- tape
?@ man (trip man)
(weld (trip -.man) `tape`[':' (trip +.man)])
:: :: ++clot:en-xml:html
++ clot ~+ :: self-closing tags
%~ has in
%- silt ^- (list term) :~
%area %base %br %col %command %embed %hr %img %inputt
%keygen %link %meta %param %source %track %wbr
==
-- ::en-xml
:: :: ++de-xml:html
++ de-xml :: xml parser
=< |=(a=cord (rush a apex))
|_ ent=_`(map term @t)`[[%apos '\''] ~ ~]
:: :: ++apex:de-xml:html
++ apex :: top level
=+ spa=;~(pose comt whit)
%+ knee *manx |. ~+
%+ ifix
[;~(plug (punt decl) (star spa)) (star spa)]
;~ pose
%+ sear |=([a=marx b=marl c=mane] ?.(=(c n.a) ~ (some [a b])))
;~(plug head many tail)
empt
==
:: :: ++attr:de-xml:html
++ attr :: attributes
%+ knee *mart |. ~+
%- star
;~ plug
;~(pfix (plus whit) name)
;~ pose
%+ ifix
:_ doq
;~(plug (ifix [. .]:(star whit) tis) doq)
(star ;~(less doq escp))
::
%+ ifix
:_ soq
;~(plug (ifix [. .]:(star whit) tis) soq)
(star ;~(less soq escp))
::
(easy ~)
==
==
:: :: ++cdat:de-xml:html
++ cdat :: CDATA section
%+ cook
|=(a=tape ^-(mars ;/(a)))
%+ ifix
[(jest '<![CDATA[') (jest ']]>')]
%- star
;~(less (jest ']]>') next)
:: :: ++chrd:de-xml:html
++ chrd :: character data
%+ cook |=(a=tape ^-(mars ;/(a)))
(plus ;~(less doq ;~(pose (just `@`10) escp)))
:: :: ++comt:de-xml:html
++ comt :: comments
=- (ifix [(jest '<!--') (jest '-->')] (star -))
;~ pose
;~(less hep prn)
whit
;~(less (jest '-->') hep)
==
::
++ decl :: ++decl:de-xml:html
%+ ifix :: XML declaration
[(jest '<?xml') (jest '?>')]
%- star
;~(less (jest '?>') prn)
:: :: ++escp:de-xml:html
++ escp ::
;~(pose ;~(less gal gar pam prn) enty)
:: :: ++enty:de-xml:html
++ enty :: entity
%+ ifix pam^mic
;~ pose
=+ def=^+(ent (my:nl [%gt '>'] [%lt '<'] [%amp '&'] [%quot '"'] ~))
%+ sear ~(get by (~(uni by def) ent))
(cook crip ;~(plug alf (stun 1^31 aln)))
%+ cook |=(a=@c ?:((gth a 0x10.ffff) '<27>' (tuft a)))
=< ;~(pfix hax ;~(pose - +))
:- (bass 10 (stun 1^8 dit))
(bass 16 ;~(pfix (mask "xX") (stun 1^8 hit)))
==
:: :: ++empt:de-xml:html
++ empt :: self-closing tag
%+ ifix [gal (jest '/>')]
;~(plug ;~(plug name attr) (cold ~ (star whit)))
:: :: ++head:de-xml:html
++ head :: opening tag
(ifix [gal gar] ;~(plug name attr))
:: :: ++many:de-xml:html
++ many :: contents
;~(pfix (star comt) (star ;~(sfix ;~(pose apex chrd cdat) (star comt))))
:: :: ++name:de-xml:html
++ name :: tag name
=+ ^= chx
%+ cook crip
;~ plug
;~(pose cab alf)
(star ;~(pose cab dot alp))
==
;~(pose ;~(plug ;~(sfix chx col) chx) chx)
:: :: ++tail:de-xml:html
++ tail :: closing tag
(ifix [(jest '</') gar] name)
:: :: ++whit:de-xml:html
++ whit :: whitespace
(mask ~[' ' `@`0x9 `@`0xa])
-- ::de-xml
:: :: ++en-urlt:html
++ en-urlt :: url encode
|= tep=tape
^- tape
%- zing
%+ turn tep
|= tap=char
=+ xen=|=(tig=@ ?:((gte tig 10) (add tig 55) (add tig '0')))
?: ?| &((gte tap 'a') (lte tap 'z'))
&((gte tap 'A') (lte tap 'Z'))
&((gte tap '0') (lte tap '9'))
=('.' tap)
=('-' tap)
=('~' tap)
=('_' tap)
==
[tap ~]
['%' (xen (rsh [0 4] tap)) (xen (end [0 4] tap)) ~]
:: :: ++de-urlt:html
++ de-urlt :: url decode
|= tep=tape
^- (unit tape)
?~ tep [~ ~]
?: =('%' i.tep)
?. ?=([@ @ *] t.tep) ~
=+ nag=(mix i.t.tep (lsh 3 i.t.t.tep))
=+ val=(rush nag hex:ag)
?~ val ~
=+ nex=$(tep t.t.t.tep)
?~(nex ~ [~ [`@`u.val u.nex]])
=+ nex=$(tep t.tep)
?~(nex ~ [~ i.tep u.nex])
:: :: ++en-purl:html
++ en-purl :: print purl
=< |=(pul=purl `tape`(apex %& pul))
|%
:: :: ++apex:en-purl:html
++ apex ::
|= qur=quri ^- tape
?- -.qur
%& (weld (head p.p.qur) `tape`$(qur [%| +.p.qur]))
%| ['/' (weld (body p.qur) (tail q.qur))]
==
:: :: ++apix:en-purl:html
++ apix :: purf to tape
|= purf
(weld (apex %& p) ?~(q "" `tape`['#' (trip u.q)]))
:: :: ++body:en-purl:html
++ body ::
|= pok=pork ^- tape
?~ q.pok ~
|-
=+ seg=(en-urlt (trip i.q.pok))
?~ t.q.pok
?~(p.pok seg (welp seg '.' (trip u.p.pok)))
(welp seg '/' $(q.pok t.q.pok))
:: :: ++head:en-purl:html
++ head ::
|= har=hart
^- tape
;: weld
?:(&(p.har !?=(hoke r.har)) "https://" "http://")
::
?- -.r.har
%| (trip (rsh 3 (scot %if p.r.har)))
%& =+ rit=(flop p.r.har)
|- ^- tape
?~ rit ~
(weld (trip i.rit) ?~(t.rit "" `tape`['.' $(rit t.rit)]))
==
::
?~(q.har ~ `tape`[':' ((d-co:co 1) u.q.har)])
==
:: :: ++tail:en-purl:html
++ tail ::
|= kay=quay
^- tape
?: =(~ kay) ~
:- '?'
|- ^- tape
?~ kay ~
;: welp
(en-urlt (trip p.i.kay))
?~(q.i.kay ~ ['=' (en-urlt (trip q.i.kay))])
?~(t.kay ~ `tape`['&' $(kay t.kay)])
==
-- ::
:: :: ++de-purl:html
++ de-purl :: url+header parser
=< |=(a=cord `(unit purl)`(rush a auri))
|%
:: :: ++deft:de-purl:html
++ deft :: parse url extension
|= rax=(list @t)
|- ^- pork
?~ rax
[~ ~]
?^ t.rax
[p.pok [ire q.pok]]:[pok=$(rax t.rax) ire=i.rax]
=/ raf=(like term)
%- ;~ sfix
%+ sear
|=(a=@ ((sand %ta) (crip (flop (trip a)))))
(cook |=(a=tape (rap 3 ^-((list @) a))) (star aln))
dot
==
[1^1 (flop (trip i.rax))]
?~ q.raf
[~ [i.rax ~]]
=+ `[ext=term [@ @] fyl=tape]`u.q.raf
:- `ext
?:(=(~ fyl) ~ [(crip (flop fyl)) ~])
:: :: ++apat:de-purl:html
++ apat :: 2396 abs_path
%+ cook deft
;~(pfix fas (more fas smeg))
:: :: ++aurf:de-purl:html
++ aurf :: 2396 with fragment
%+ cook |~(a=purf a)
;~(plug auri (punt ;~(pfix hax (cook crip (star pque)))))
:: :: ++auri:de-purl:html
++ auri :: 2396 URL
;~ plug
;~(plug htts thor)
;~(plug ;~(pose apat (easy *pork)) yque)
==
:: :: ++auru:de-purl:html
++ auru :: 2396 with maybe user
%+ cook
|= $: a=[p=? q=(unit user) r=[(unit @ud) host]]
b=[pork quay]
==
^- (pair (unit user) purl)
[q.a [[p.a r.a] b]]
::
;~ plug
;~(plug htts (punt ;~(sfix urt:ab pat)) thor)
;~(plug ;~(pose apat (easy *pork)) yque)
==
:: :: ++htts:de-purl:html
++ htts :: scheme
%+ sear ~(get by (malt `(list (pair term ?))`[http+| https+& ~]))
;~(sfix scem ;~(plug col fas fas))
:: :: ++cock:de-purl:html
++ cock :: cookie
%+ most ;~(plug mic ace)
;~(plug toke ;~(pfix tis tosk))
:: :: ++dlab:de-purl:html
++ dlab :: 2396 domainlabel
%+ sear
|= a=@ta
?.(=('-' (rsh [3 (dec (met 3 a))] a)) [~ u=a] ~)
%+ cook |=(a=tape (crip (cass a)))
;~(plug aln (star alp))
:: :: ++fque:de-purl:html
++ fque :: normal query field
(cook crip (plus pquo))
:: :: ++fquu:de-purl:html
++ fquu :: optional query field
(cook crip (star pquo))
:: :: ++pcar:de-purl:html
++ pcar :: 2396 path char
;~(pose pure pesc psub col pat)
:: :: ++pcok:de-purl:html
++ pcok :: cookie char
;~(less bas mic com doq prn)
:: :: ++pesc:de-purl:html
++ pesc :: 2396 escaped
;~(pfix cen mes)
:: :: ++pold:de-purl:html
++ pold ::
(cold ' ' (just '+'))
:: :: ++pque:de-purl:html
++ pque :: 3986 query char
;~(pose pcar fas wut)
:: :: ++pquo:de-purl:html
++ pquo :: normal query char
;~(pose pure pesc pold fas wut col com)
:: :: ++pure:de-purl:html
++ pure :: 2396 unreserved
;~(pose aln hep cab dot zap sig tar soq pal par)
:: :: ++psub:de-purl:html
++ psub :: 3986 sub-delims
;~ pose
zap buc pam soq pal par
tar lus com mic tis
==
:: :: ++ptok:de-purl:html
++ ptok :: 2616 token
;~ pose
aln zap hax buc cen pam soq tar lus
hep dot ket cab tic bar sig
==
:: :: ++scem:de-purl:html
++ scem :: 2396 scheme
%+ cook |=(a=tape (crip (cass a)))
;~(plug alf (star ;~(pose aln lus hep dot)))
:: :: ++smeg:de-purl:html
++ smeg :: 2396 segment
(cook crip (star pcar))
:: :: ++tock:de-purl:html
++ tock :: 6265 raw value
(cook crip (plus pcok))
:: :: ++tosk:de-purl:html
++ tosk :: 6265 quoted value
;~(pose tock (ifix [doq doq] tock))
:: :: ++toke:de-purl:html
++ toke :: 2616 token
(cook crip (plus ptok))
:: :: ++thor:de-purl:html
++ thor :: 2396 host+port
%+ cook |*([* *] [+<+ +<-])
;~ plug
thos
;~((bend) (easy ~) ;~(pfix col dim:ag))
==
:: :: ++thos:de-purl:html
++ thos :: 2396 host, no local
;~ plug
;~ pose
%+ stag %&
%+ sear :: LL parser weak here
|= a=(list @t)
=+ b=(flop a)
?> ?=(^ b)
=+ c=(end 3 i.b)
?.(&((gte c 'a') (lte c 'z')) ~ [~ u=b])
(most dot dlab)
::
%+ stag %|
=+ tod=(ape:ag ted:ab)
%+ bass 256
;~(plug tod (stun [3 3] ;~(pfix dot tod)))
==
==
:: :: ++yque:de-purl:html
++ yque :: query ending
;~ pose
;~(pfix wut yquy)
(easy ~)
==
:: :: ++yquy:de-purl:html
++ yquy :: query
;~ pose
:: proper query
::
%+ more
;~(pose pam mic)
;~(plug fque ;~(pose ;~(pfix tis fquu) (easy '')))
::
:: funky query
::
%+ cook
|=(a=tape [[%$ (crip a)] ~])
(star pque)
==
:: :: ++zest:de-purl:html
++ zest :: 2616 request-uri
;~ pose
(stag %& (cook |=(a=purl a) auri))
(stag %| ;~(plug apat yque))
==
-- ::de-purl
:: +en-turf: encode +turf as a TLD-last domain string
::
++ en-turf
|= =turf
^- @t
(rap 3 (flop (join '.' turf)))
:: +de-turf: parse a TLD-last domain string into a TLD first +turf
::
++ de-turf
|= host=@t
^- (unit turf)
%+ rush host
%+ sear
|= =host:eyre
?.(?=(%& -.host) ~ (some p.host))
thos:de-purl:html
::
:: MOVEME
:: :: ++fuel:html
++ fuel :: parse urbit fcgi
|= [bem=beam ced=noun:cred quy=quer]
^- epic
=+ qix=|-(`quay`?~(quy quy [[p q]:quy $(quy t.quy)]))
[(malt qix) ;;(cred ced) bem]
::
++ hiss-to-request
|= =hiss
^- request:http
::
:* ?- p.q.hiss
%conn %'CONNECT'
%delt %'DELETE'
%get %'GET'
%head %'HEAD'
%opts %'OPTIONS'
%post %'POST'
%put %'PUT'
%trac %'TRACE'
==
::
(crip (en-purl:html p.hiss))
::
^- header-list:http
~! q.q.hiss
%+ turn ~(tap by q.q.hiss)
|= [a=@t b=(list @t)]
^- [@t @t]
?> ?=(^ b)
[a i.b]
::
r.q.hiss
==
-- :: html
:: ::
:::: ++wired :: wire formatting
:: ::::
++ wired ^?
|%
:: :: ++dray:wired
++ dray :: load tuple in path
::
:: .= ~[p=~.ack q=~.~sarnel r=~..y]
:: (dray ~[p=%tas q=%p r=%f] %ack ~sarnel &)
::
=- |* [a=[@tas (pole @tas)] b=*] ^- (paf a)
=> .(b `,(tup -.a +.a)`b)
?~ +.a [(scot -.a b) ~]
[(scot -.a -.b) `,(paf +.a)`(..$ +.a +.b)]
:- paf=|*(a=(pole) ?~(a ,~ ,[(odo:raid ,-.a(. %ta)) ,(..$ +.a)]))
^= tup
|* [a=@tas b=(pole @tas)]
=+ c=(odo:raid a)
?~(b c ,[c (..$ ,-.b ,+.b)])
:: :: ++raid:wired
++ raid :: demand path odors
::
:: .= [p=%ack q=~sarnel r=&]
:: (raid /ack/~sarnel+.y p=%tas q=%p r=%f ~)
::
=- |* [a=path b=[@tas (pole @tas)]]
=* fog (odo -.b)
?~ +.b `fog`(slav -.b -.a)
[`fog`(slav -.b -.a) (..$ +.a +.b)]
^= odo
|* a=@tas
|= b=*
=- a(, (- b)) :: preserve face
?+ a @
%c @c %da @da %dr @dr %f @f %if @if %is @is %p @p
%u @u %uc @uc %ub @ub %ui @ui %ux @ux %uv @uv %uw @uw
%s @s %t @t %ta @ta %tas @tas
==
:: :: :: ++read:wired
:: ++ read :: parse odored path
:: =< |*([a=path b=[@tas (pole @tas)]] ((+> b) a))
:: |* b=[@tas (pole @tas)]
:: |= a=path
:: ?~ a ~
:: =+ hed=(slaw -.b i.a)
:: =* fog (odo:raid -.b)
:: ?~ +.b
:: ^- (unit fog)
:: ?^(+.a ~ hed)
:: ^- (unit [fog _(need *(..^$ +.b))])
:: (both hed ((..^$ +.b) +.a))
-- ::wired
:: ::
:::: ++title :: (2j) identity
:: ::::
++ title
:: deep core: for vane use, with $roof for scrying
::
:: TODO: refactor to share high-level gates like +saxo
:: among the three cores
::
=> |%
++ sein
|= [rof=roof our=ship now=@da who=ship]
;; ship
=< q.q %- need %- need
(rof ~ %j `beam`[[our %sein %da now] /(scot %p who)])
--
:: middle core: for userspace use, with .^
::
=> |%
:: :: ++clan:title
++ clan :: ship to rank
|= who=ship
^- rank
=/ wid (met 3 who)
?: (lte wid 1) %czar
?: =(2 wid) %king
?: (lte wid 4) %duke
?: (lte wid 8) %earl
?> (lte wid 16) %pawn
:: :: ++rank:title
+$ rank ?(%czar %king %duke %earl %pawn) :: ship width class
:: :: ++name:title
++ name :: identity
|= who=ship
^- ship
?. ?=(%earl (clan who)) who
(sein who)
:: :: ++saxo:title
++ saxo :: autocanon
|= who=ship
^- (list ship)
=/ dad (sein who)
[who ?:(=(who dad) ~ $(who dad))]
:: :: ++sein:title
++ sein :: autoboss
|= who=ship
^- ship
=/ mir (clan who)
?- mir
%czar who
%king (end 3 who)
%duke (end 4 who)
%earl (end 5 who)
%pawn (end 4 who)
==
--
:: surface core: stateless queries for default numeric sponsorship
::
|%
:: :: ++cite:title
++ cite :: render ship
|= who=@p
^- tape
=+ kind=(clan who)
=+ name=(scow %p who)
?: =(%earl kind)
:(weld "~" (swag [15 6] name) "^" (swag [22 6] name))
?: =(%pawn kind)
:(weld (swag [0 7] name) "_" (swag [51 6] name))
name
:: :: ++saxo:title
++ saxo :: autocanon
|= [our=ship now=@da who=ship]
.^ (list ship)
%j
/(scot %p our)/saxo/(scot %da now)/(scot %p who)
==
:: :: ++sein:title
++ sein :: autoboss
|= [our=ship now=@da who=ship]
.^ ship
%j
/(scot %p our)/sein/(scot %da now)/(scot %p who)
==
:: :: ++team:title
++ team :: our / our moon
|= [our=ship who=ship]
^- ?
?| =(our who)
&(?=(%earl (clan who)) =(our (^sein who)))
==
-- ::title
:: ::
:::: ++milly :: (2k) milliseconds
:: ::::
++ milly ^|
|_ now=@da
:: :: ++around:milly
++ around :: relative msec
|= wen=@da
^- @tas
?: =(wen now) %now
?: (gth wen now)
(cat 3 (scot %ud (msec (sub wen now))) %ms)
(cat 3 '-' $(now wen, wen now))
::
++ about :: ++about:milly
|= wun=(unit @da) :: unit relative msec
^- @tas
?~(wun %no (around u.wun))
:: :: ++mill:milly
++ mill :: msec diff
|= one=@dr
^- @tas
?: =(`@`0 one) '0ms'
(cat 3 (scot %ud (msec one)) %ms)
:: :: ++msec:milly
++ msec :: @dr to @ud ms
|=(a=@dr `@ud`(div a (div ~s1 1.000)))
:: :: ++mull:milly
++ mull :: unit msec diff
|= une=(unit @dr)
^- @tas
?~(une %no (mill u.une))
--
::
::::
::
++ contain ^?
|%
:: +by-clock: interface core for a cache using the clock replacement algorithm
::
:: Presents an interface for a mapping, but somewhat specialized, and with
:: stateful accessors. The clock's :depth parameter is used as the maximum
:: freshness that an entry can have. The standard clock algorithm has a depth
:: of 1, meaning that a single sweep of the arm will delete the entry. For
:: more scan resistance, :depth can be set to a higher number.
::
:: Internally, :clock maintains a :lookup of type
:: `(map key-type [val=val-type fresh=@ud])`, where :depth.clock is the
:: maximum value of :fresh. Looking up a key increments its freshness, and a
:: sweep of the clock arm decrements its freshness.
::
:: The clock arm is stored as :queue, which is a `(qeu key-type)`. The head
:: of the queue represents the position of the clock arm. New entries are
:: inserted at the tail of the queue. When the clock arm sweeps, it
:: pops the head off the queue. If the :fresh of the head's entry in :lookup
:: is 0, remove the entry from the mapping and replace it with the new entry.
:: Otherwise, decrement the entry's freshness, put it back at the tail of
:: the queue, and pop the next head off the queue and try again.
::
:: Cache entries must be immutable: a key cannot be overwritten with a new
:: value. This property is enforced for entries currently stored in the
:: cache, but it is not enforced for previously deleted entries, since we
:: no longer remember what that key's value was supposed to be.
::
++ by-clock
|* [key-type=mold val-type=mold]
|_ clock=(clock key-type val-type)
:: +get: looks up a key, marking it as fresh
::
++ get
|= key=key-type
^- [(unit val-type) _clock]
::
=+ maybe-got=(~(get by lookup.clock) key)
?~ maybe-got
[~ clock]
::
=. clock (freshen key)
::
[`val.u.maybe-got clock]
:: +put: add a new cache entry, possibly removing an old one
::
++ put
|= [key=key-type val=val-type]
^+ clock
:: do nothing if our size is 0 so we don't decrement-underflow
::
?: =(0 max-size.clock)
clock
:: no overwrite allowed, but allow duplicate puts
::
?^ existing=(~(get by lookup.clock) key)
:: val must not change
::
?> =(val val.u.existing)
::
(freshen key)
::
=? clock =(max-size.clock size.clock)
evict
::
%_ clock
size +(size.clock)
lookup (~(put by lookup.clock) key [val 1])
queue (~(put to queue.clock) key)
==
:: +freshen: increment the protection level on an entry
::
++ freshen
|= key=key-type
^+ clock
%_ clock
lookup
%+ ~(jab by lookup.clock) key
|= entry=[val=val-type fresh=@ud]
entry(fresh (min +(fresh.entry) depth.clock))
==
:: +resize: changes the maximum size, removing entries if needed
::
++ resize
|= new-max=@ud
^+ clock
::
=. max-size.clock new-max
::
?: (gte new-max size.clock)
clock
::
(trim (sub size.clock new-max))
:: +evict: remove an entry from the cache
::
++ evict
^+ clock
::
=. size.clock (dec size.clock)
::
|-
^+ clock
::
=^ old-key queue.clock ~(get to queue.clock)
=/ old-entry (~(got by lookup.clock) old-key)
::
?: =(0 fresh.old-entry)
clock(lookup (~(del by lookup.clock) old-key))
::
%_ $
lookup.clock
(~(put by lookup.clock) old-key old-entry(fresh (dec fresh.old-entry)))
::
queue.clock
(~(put to queue.clock) old-key)
==
:: +trim: remove :count entries from the cache
::
++ trim
|= count=@ud
^+ clock
?: =(0 count)
clock
$(count (dec count), clock evict)
:: +purge: removes all cache entries
::
++ purge
^+ clock
%_ clock
lookup ~
queue ~
size 0
==
--
:: +to-capped-queue: interface door for +capped-queue
::
:: Provides a queue of a limited size where pushing additional items will
:: force pop the items at the front of the queue.
::
++ to-capped-queue
|* item-type=mold
|_ queue=(capped-queue item-type)
:: +put: enqueue :item, possibly popping and producing an old item
::
++ put
|= item=item-type
^- [(unit item-type) _queue]
:: are we already at max capacity?
::
?. =(size.queue max-size.queue)
:: we're below max capacity, so push and increment size
::
=. queue.queue (~(put to queue.queue) item)
=. size.queue +(size.queue)
::
[~ queue]
:: max is zero, the oldest item to return is the one which just went in.
::
?: =(~ queue.queue)
[`item queue]
:: we're at max capacity, so pop before pushing; size is unchanged
::
=^ oldest queue.queue ~(get to queue.queue)
=. queue.queue (~(put to queue.queue) item)
::
[`oldest queue]
:: +get: pop an item off the queue, adjusting size
::
++ get
^- [item-type _queue]
::
=. size.queue (dec size.queue)
=^ oldest queue.queue ~(get to queue.queue)
::
[oldest queue]
:: change the :max-size of the queue, popping items if necessary
::
++ resize
=| pops=(list item-type)
|= new-max=@ud
^+ [pops queue]
:: we're not overfull, so no need to pop off more items
::
?: (gte new-max size.queue)
[(flop pops) queue(max-size new-max)]
:: we're above capacity; pop an item off and recurse
::
=^ oldest queue get
::
$(pops [oldest pops])
--
--
::
:: +mop: constructs and validates ordered ordered map based on key,
:: val, and comparator gate
::
++ mop
|* [key=mold value=mold]
|= ord=$-([key key] ?)
|= a=*
=/ b ;;((tree [key=key val=value]) a)
?> (apt:((on key value) ord) b)
b
::
::
++ ordered-map on
:: +on: treap with user-specified horizontal order, ordered-map
::
:: WARNING: ordered-map will not work properly if two keys can be
:: unequal under noun equality but equal via the compare gate
::
++ on
~/ %on
|* [key=mold val=mold]
=> |%
+$ item [key=key val=val]
--
:: +compare: item comparator for horizontal order
::
~% %comp +>+ ~
|= compare=$-([key key] ?)
~% %core + ~
|%
:: +all: apply logical AND boolean test on all values
::
++ all
~/ %all
|= [a=(tree item) b=$-(item ?)]
^- ?
|-
?~ a
&
?&((b n.a) $(a l.a) $(a r.a))
:: +any: apply logical OR boolean test on all values
::
++ any
~/ %any
|= [a=(tree item) b=$-(item ?)]
|- ^- ?
?~ a
|
?|((b n.a) $(a l.a) $(a r.a))
:: +apt: verify horizontal and vertical orderings
::
++ apt
~/ %apt
|= a=(tree item)
=| [l=(unit key) r=(unit key)]
|- ^- ?
:: empty tree is valid
::
?~ a %.y
:: nonempty trees must maintain several criteria
::
?& :: if .n.a is left of .u.l, assert horizontal comparator
::
?~(l %.y (compare key.n.a u.l))
:: if .n.a is right of .u.r, assert horizontal comparator
::
?~(r %.y (compare u.r key.n.a))
:: if .a is not leftmost element, assert vertical order between
:: .l.a and .n.a and recurse to the left with .n.a as right
:: neighbor
::
?~(l.a %.y &((mor key.n.a key.n.l.a) $(a l.a, l `key.n.a)))
:: if .a is not rightmost element, assert vertical order
:: between .r.a and .n.a and recurse to the right with .n.a as
:: left neighbor
::
?~(r.a %.y &((mor key.n.a key.n.r.a) $(a r.a, r `key.n.a)))
==
:: +bap: convert to list, right to left
::
++ bap
~/ %bap
|= a=(tree item)
^- (list item)
=| b=(list item)
|- ^+ b
?~ a b
$(a r.a, b [n.a $(a l.a)])
:: +del: delete .key from .a if it exists, producing value iff deleted
::
++ del
~/ %del
|= [a=(tree item) =key]
^- [(unit val) (tree item)]
?~ a [~ ~]
:: we found .key at the root; delete and rebalance
::
?: =(key key.n.a)
[`val.n.a (nip a)]
:: recurse left or right to find .key
::
?: (compare key key.n.a)
=+ [found lef]=$(a l.a)
[found a(l lef)]
=+ [found rig]=$(a r.a)
[found a(r rig)]
:: +dip: stateful partial inorder traversal
::
:: Mutates .state on each run of .f. Starts at .start key, or if
:: .start is ~, starts at the head. Stops when .f produces .stop=%.y.
:: Traverses from left to right keys.
:: Each run of .f can replace an item's value or delete the item.
::
++ dip
~/ %dip
|* state=mold
|= $: a=(tree item)
=state
f=$-([state item] [(unit val) ? state])
==
^+ [state a]
:: acc: accumulator
::
:: .stop: set to %.y by .f when done traversing
:: .state: threaded through each run of .f and produced by +abet
::
=/ acc [stop=`?`%.n state=state]
=< abet =< main
|%
++ this .
++ abet [state.acc a]
:: +main: main recursive loop; performs a partial inorder traversal
::
++ main
^+ this
:: stop if empty or we've been told to stop
::
?: =(~ a) this
?: stop.acc this
:: inorder traversal: left -> node -> right, until .f sets .stop
::
=. this left
?: stop.acc this
=^ del this node
=? this !stop.acc right
=? a del (nip a)
this
:: +node: run .f on .n.a, updating .a, .state, and .stop
::
++ node
^+ [del=*? this]
:: run .f on node, updating .stop.acc and .state.acc
::
?> ?=(^ a)
=^ res acc (f state.acc n.a)
?~ res
[del=& this]
[del=| this(val.n.a u.res)]
:: +left: recurse on left subtree, copying mutant back into .l.a
::
++ left
^+ this
?~ a this
=/ lef main(a l.a)
lef(a a(l a.lef))
:: +right: recurse on right subtree, copying mutant back into .r.a
::
++ right
^+ this
?~ a this
=/ rig main(a r.a)
rig(a a(r a.rig))
--
:: +gas: put a list of items
::
++ gas
~/ %gas
|= [a=(tree item) b=(list item)]
^- (tree item)
?~ b a
$(b t.b, a (put a i.b))
:: +get: get val at key or return ~
::
++ get
~/ %get
|= [a=(tree item) b=key]
^- (unit val)
?~ a ~
?: =(b key.n.a)
`val.n.a
?: (compare b key.n.a)
$(a l.a)
$(a r.a)
:: +got: need value at key
::
++ got
|= [a=(tree item) b=key]
^- val
(need (get a b))
:: +has: check for key existence
::
++ has
~/ %has
|= [a=(tree item) b=key]
^- ?
!=(~ (get a b))
:: +lot: take a subset range excluding start and/or end and all elements
:: outside the range
::
++ lot
~/ %lot
|= $: tre=(tree item)
start=(unit key)
end=(unit key)
==
^- (tree item)
|^
?: ?&(?=(~ start) ?=(~ end))
tre
?~ start
(del-span tre %end end)
?~ end
(del-span tre %start start)
?> (compare u.start u.end)
=. tre (del-span tre %start start)
(del-span tre %end end)
::
++ del-span
|= [a=(tree item) b=?(%start %end) c=(unit key)]
^- (tree item)
?~ a a
?~ c a
?- b
%start
:: found key
?: =(key.n.a u.c)
(nip a(l ~))
:: traverse to find key
?: (compare key.n.a u.c)
:: found key to the left of start
$(a (nip a(l ~)))
:: found key to the right of start
a(l $(a l.a))
::
%end
:: found key
?: =(u.c key.n.a)
(nip a(r ~))
:: traverse to find key
?: (compare key.n.a u.c)
:: found key to the left of end
a(r $(a r.a))
:: found key to the right of end
$(a (nip a(r ~)))
==
--
:: +nip: remove root; for internal use
::
++ nip
~/ %nip
|= a=(tree item)
^- (tree item)
?> ?=(^ a)
:: delete .n.a; merge and balance .l.a and .r.a
::
|- ^- (tree item)
?~ l.a r.a
?~ r.a l.a
?: (mor key.n.l.a key.n.r.a)
l.a(r $(l.a r.l.a))
r.a(l $(r.a l.r.a))
::
:: +pop: produce .head (leftmost item) and .rest or crash if empty
::
++ pop
~/ %pop
|= a=(tree item)
^- [head=item rest=(tree item)]
?~ a !!
?~ l.a [n.a r.a]
=/ l $(a l.a)
:- head.l
:: load .rest.l back into .a and rebalance
::
?: |(?=(~ rest.l) (mor key.n.a key.n.rest.l))
a(l rest.l)
rest.l(r a(r r.rest.l))
:: +pry: produce head (leftmost item) or null
::
++ pry
~/ %pry
|= a=(tree item)
^- (unit item)
?~ a ~
|-
?~ l.a `n.a
$(a l.a)
:: +put: ordered item insert
::
++ put
~/ %put
|= [a=(tree item) =key =val]
^- (tree item)
:: base case: replace null with single-item tree
::
?~ a [n=[key val] l=~ r=~]
:: base case: overwrite existing .key with new .val
::
?: =(key.n.a key) a(val.n val)
:: if item goes on left, recurse left then rebalance vertical order
::
?: (compare key key.n.a)
=/ l $(a l.a)
?> ?=(^ l)
?: (mor key.n.a key.n.l)
a(l l)
l(r a(l r.l))
:: item goes on right; recurse right then rebalance vertical order
::
=/ r $(a r.a)
?> ?=(^ r)
?: (mor key.n.a key.n.r)
a(r r)
r(l a(r l.r))
:: +ram: produce tail (rightmost item) or null
::
++ ram
~/ %ram
|= a=(tree item)
^- (unit item)
?~ a ~
|-
?~ r.a `n.a
$(a r.a)
:: +run: apply gate to transform all values in place
::
++ run
~/ %run
|* [a=(tree item) b=$-(val *)]
|-
?~ a a
[n=[key.n.a (b val.n.a)] l=$(a l.a) r=$(a r.a)]
:: +tab: tabulate a subset excluding start element with a max count
::
++ tab
~/ %tab
|= [a=(tree item) b=(unit key) c=@]
^- (list item)
|^
(flop e:(tabulate (del-span a b) b c))
::
++ tabulate
|= [a=(tree item) b=(unit key) c=@]
^- [d=@ e=(list item)]
?: ?&(?=(~ b) =(c 0))
[0 ~]
=| f=[d=@ e=(list item)]
|- ^+ f
?: ?|(?=(~ a) =(d.f c)) f
=. f $(a l.a)
?: =(d.f c) f
=. f [+(d.f) [n.a e.f]]
?:(=(d.f c) f $(a r.a))
::
++ del-span
|= [a=(tree item) b=(unit key)]
^- (tree item)
?~ a a
?~ b a
?: =(key.n.a u.b)
r.a
?: (compare key.n.a u.b)
$(a r.a)
a(l $(a l.a))
--
:: +tap: convert to list, left to right
::
++ tap
~/ %tap
|= a=(tree item)
^- (list item)
=| b=(list item)
|- ^+ b
?~ a b
$(a l.a, b [n.a $(a r.a)])
:: +uni: unify two ordered maps
::
:: .b takes precedence over .a if keys overlap.
::
++ uni
~/ %uni
|= [a=(tree item) b=(tree item)]
^- (tree item)
?~ b a
?~ a b
?: =(key.n.a key.n.b)
[n=n.b l=$(a l.a, b l.b) r=$(a r.a, b r.b)]
?: (mor key.n.a key.n.b)
?: (compare key.n.b key.n.a)
$(l.a $(a l.a, r.b ~), b r.b)
$(r.a $(a r.a, l.b ~), b l.b)
?: (compare key.n.a key.n.b)
$(l.b $(b l.b, r.a ~), a r.a)
$(r.b $(b r.b, l.a ~), a l.a)
--
:: ::
:::: ++userlib :: (2u) non-vane utils
:: ::::
++ userlib ^?
|%
:: ::
:::: ++chrono:userlib :: (2uB) time
:: ::::
++ chrono ^?
|%
:: +from-unix: unix seconds to @da
::
++ from-unix
|= timestamp=@ud
^- @da
%+ add ~1970.1.1
(mul timestamp ~s1)
:: +from-unix-ms: unix milliseconds to @da
::
++ from-unix-ms
|= timestamp=@ud
^- @da
%+ add ~1970.1.1
(div (mul ~s1 timestamp) 1.000)
:: :: ++dawn:chrono:
++ dawn :: Jan 1 weekday
|= yer=@ud
=+ yet=(sub yer 1)
%- mod :_ 7
;: add
1
(mul 5 (mod yet 4))
(mul 4 (mod yet 100))
(mul 6 (mod yet 400))
==
:: :: ++daws:chrono:
++ daws :: date weekday
|= yed=date
%- mod :_ 7
%+ add
(dawn y.yed)
(sub (yawn [y.yed m.yed d.t.yed]) (yawn y.yed 1 1))
:: :: ++deal:chrono:
++ deal :: to leap sec time
|= yer=@da
=+ n=0
=+ yud=(yore yer)
|- ^- date
?: (gte yer (add (snag n lef:yu) ~s1))
(yore (year yud(s.t (add n s.t.yud))))
?: &((gte yer (snag n lef:yu)) (lth yer (add (snag n lef:yu) ~s1)))
yud(s.t (add +(n) s.t.yud))
?: =(+(n) (lent lef:yu))
(yore (year yud(s.t (add +(n) s.t.yud))))
$(n +(n))
:: :: ++lead:chrono:
++ lead :: from leap sec time
|= ley=date
=+ ler=(year ley)
=+ n=0
|- ^- @da
=+ led=(sub ler (mul n ~s1))
?: (gte ler (add (snag n les:yu) ~s1))
led
?: &((gte ler (snag n les:yu)) (lth ler (add (snag n les:yu) ~s1)))
?: =(s.t.ley 60)
(sub led ~s1)
led
?: =(+(n) (lent les:yu))
(sub led ~s1)
$(n +(n))
:: :: ++dust:chrono:
++ dust :: print UTC format
|= yed=date
^- tape
=+ wey=(daws yed)
=/ num (d-co:co 1) :: print as decimal without dots
=/ pik |=([n=@u t=wall] `tape`(scag 3 (snag n t)))
::
"{(pik wey wik:yu)}, ".
"{(num d.t.yed)} {(pik (dec m.yed) mon:yu)} {(num y.yed)} ".
"{(num h.t.yed)}:{(num m.t.yed)}:{(num s.t.yed)} +0000"
:: :: ++stud:chrono:
++ stud :: parse UTC format
=< |= a=cord :: expose parsers
%+ biff (rush a (more sepa elem))
|= b=(list _(wonk *elem)) ^- (unit date)
=- ?.((za:dejs:format -) ~ (some (zp:dejs:format -)))
^+ =+ [*date u=unit]
*[(u _[a y]) (u _m) (u _d.t) (u _+.t) ~]
:~
|-(?~(b ~ ?.(?=(%y -.i.b) $(b t.b) `+.i.b)))
|-(?~(b ~ ?.(?=(%m -.i.b) $(b t.b) `+.i.b)))
|-(?~(b ~ ?.(?=(%d -.i.b) $(b t.b) `+.i.b)))
|-(?~(b ~ ?.(?=(%t -.i.b) $(b t.b) `+.i.b)))
==
|%
:: :: ++snug:stud:chrono:
++ snug :: position in list
|= a=(list tape)
|= b=tape
=+ [pos=1 len=(lent b)]
|- ^- (unit @u)
?~ a ~
?: =(b (scag len i.a))
`pos
$(pos +(pos), a t.a)
:: :: ++sepa:stud:chrono:
++ sepa :: separator
;~(pose ;~(plug com (star ace)) (plus ace))
:: :: ++elem:stud:chrono:
++ elem :: date element
;~ pose
(stag %t t) (stag %y y) (stag %m m) (stag %d d)
(stag %w w) (stag %z z)
==
:: :: ++y:stud:chrono:
++ y :: year
(stag %& (bass 10 (stun 3^4 dit)))
:: :: ++m:stud:chrono:
++ m :: month
(sear (snug mon:yu) (plus alf))
:: :: ++d:stud:chrono:
++ d :: day
(bass 10 (stun 1^2 dit))
:: :: ++t:stud:chrono:
++ t :: hours:minutes:secs
%+ cook |=([h=@u @ m=@u @ s=@u] ~[h m s])
;~(plug d col d col d)
::
:: XX day of week is currently unchecked, and
:: timezone outright ignored.
:: :: ++w:stud:chrono:
++ w :: day of week
(sear (snug wik:yu) (plus alf))
:: :: ++z:stud:chrono:
++ z :: time zone
;~(plug (mask "-+") dd dd)
:: :: ++dd:stud:chrono:
++ dd :: two digits
(bass 10 (stun 2^2 dit))
-- ::
:: :: ++unm:chrono:userlib
++ unm :: Urbit to Unix ms
|= a=@da
=- (div (mul - 1.000) ~s1)
(sub (add a (div ~s1 2.000)) ~1970.1.1)
:: :: ++unt:chrono:userlib
++ unt :: Urbit to Unix time
|= a=@da
(div (sub a ~1970.1.1) ~s1)
:: :: ++yu:chrono:userlib
++ yu :: UTC format constants
|%
:: :: ++mon:yu:chrono:
++ mon :: months
^- (list tape)
:~ "January" "February" "March" "April" "May" "June" "July"
"August" "September" "October" "November" "December"
==
:: :: ++wik:yu:chrono:
++ wik :: weeks
^- (list tape)
:~ "Sunday" "Monday" "Tuesday" "Wednesday" "Thursday"
"Friday" "Saturday"
==
:: :: ++lef:yu:chrono:
++ lef :: leapsecond dates
^- (list @da)
:~ ~2016.12.31..23.59.59 ~2015.6.30..23.59.59
~2012.6.30..23.59.59 ~2008.12.31..23.59.58
~2005.12.31..23.59.57 ~1998.12.31..23.59.56
~1997.6.30..23.59.55 ~1995.12.31..23.59.54
~1994.6.30..23.59.53 ~1993.6.30..23.59.52
~1992.6.30..23.59.51 ~1990.12.31..23.59.50
~1989.12.31..23.59.49 ~1987.12.31..23.59.48
~1985.6.30..23.59.47 ~1983.6.30..23.59.46
~1982.6.30..23.59.45 ~1981.6.30..23.59.44
~1979.12.31..23.59.43 ~1978.12.31..23.59.42
~1977.12.31..23.59.41 ~1976.12.31..23.59.40
~1975.12.31..23.59.39 ~1974.12.31..23.59.38
~1973.12.31..23.59.37 ~1972.12.31..23.59.36
~1972.6.30..23.59.35
==
::
:: +les:yu:chrono: leapsecond days
::
:: https://www.ietf.org/timezones/data/leap-seconds.list
::
++ les
^- (list @da)
:~ ~2017.1.1 ~2015.7.1 ~2012.7.1 ~2009.1.1 ~2006.1.1 ~1999.1.1
~1997.7.1 ~1996.1.1 ~1994.7.1 ~1993.7.1 ~1992.7.1 ~1991.1.1
~1990.1.1 ~1988.1.1 ~1985.7.1 ~1983.7.1 ~1982.7.1 ~1981.7.1
~1980.1.1 ~1979.1.1 ~1978.1.1 ~1977.1.1 ~1976.1.1 ~1975.1.1
~1974.1.1 ~1973.1.1 ~1972.7.1
==
-- ::yu
-- ::chrono
:: ::
:::: ++space:userlib :: (2uC) file utils
:: ::::
++ space ^?
=, clay
|%
:: :: ++feel:space:userlib
++ feel :: simple file write
|= [pax=path val=cage]
^- miso
=+ dir=.^(arch %cy pax)
?~ fil.dir [%ins val]
[%mut val]
:: :: ++file:space:userlib
++ file :: simple file load
|= pax=path
^- (unit)
=+ dir=.^(arch %cy pax)
?~(fil.dir ~ [~ .^(* %cx pax)])
:: :: ++foal:space:userlib
++ foal :: high-level write
|= [pax=path val=cage]
^- toro
?> ?=([* * * *] pax)
[i.t.pax [%& [[[t.t.t.pax (feel pax val)] ~]]]]
:: :: ++fray:space:userlib
++ fray :: high-level delete
|= pax=path
^- toro
?> ?=([* * * *] pax)
[i.t.pax [%& [[[t.t.t.pax [%del ~]] ~]]]]
:: :: ++furl:space:userlib
++ furl :: unify changes
|= [one=toro two=toro]
^- toro
~| %furl
?> ?& =(p.one p.two) :: same path
&(?=(%& -.q.one) ?=(%& -.q.two)) :: both deltas
==
[p.one [%& (weld p.q.one p.q.two)]]
-- ::space
:: ::
:::: ++unix:userlib :: (2uD) unix line-list
:: ::::
++ unix ^?
|%
:: :: ++lune:unix:userlib
++ lune :: cord by unix line
~% %lune ..part ~
|= txt=@t
?~ txt
^- (list @t) ~
=+ [byt=(rip 3 txt) len=(met 3 txt)]
=| [lin=(list @t) off=@]
^- (list @t)
%- flop
|- ^+ lin
?: =(off len)
~| %noeol !!
?: =((snag off byt) 10)
?: =(+(off) len)
[(rep 3 (scag off byt)) lin]
%= $
lin [(rep 3 (scag off byt)) lin]
byt (slag +(off) byt)
len (sub len +(off))
off 0
==
$(off +(off))
:: :: ++nule:unix:userlib
++ nule :: lines to unix cord
~% %nule ..part ~
|= lin=(list @t)
^- @t
%+ can 3
%+ turn lin
|= t=@t
[+((met 3 t)) (cat 3 t 10)]
--
:: ::
:::: ++scanf:userlib :: (2uF) exterpolation
:: ::::
++ scanf
=< |* [tape (pole _;/(*[$^(rule tape)]))] :: formatted scan
=> .(+< [a b]=+<)
(scan a (parsf b))
|%
:: :: ++parsf:scanf:
++ parsf :: make parser from:
|* a=(pole _;/(*[$^(rule tape)])) :: ;"chars{rule}chars"
=- (cook - (boil (norm a)))
|* (list)
?~ +< ~
?~ t i
[i $(+< t)]
::
:: .= (boil ~[[& dim] [| ", "] [& dim]]:ag)
:: ;~(plug dim ;~(pfix com ace ;~(plug dim (easy)))):ag
::
:: :: ++boil:scanf:userlib
++ boil ::
|* (list (each rule tape))
?~ +< (easy ~)
?: ?=(%| -.i) ;~(pfix (jest (crip p.i)) $(+< t))
%+ cook |*([* *] [i t]=+<)
;~(plug p.i $(+< t))
::
:: .= (norm [;"{n}, {n}"]:n=dim:ag) ~[[& dim] [| ", "] [& dim]]:ag
::
:: :: ++norm:scanf:userlib
++ norm ::
|* (pole _;/(*[$^(rule tape)]))
?~ +< ~
=> .(+< [i=+<- t=+<+])
:_ t=$(+< t)
=+ rul=->->.i
^= i
?~ rul [%| p=rul]
?~ +.rul [%| p=rul]
?@ &2.rul [%| p=;;(tape rul)]
[%& p=rul]
-- ::scanf
--
:: +harden: coerce %soft $hobo or pass-through
::
++ harden
|* task=mold
|= wrapped=(hobo task)
^- task
?. ?=(%soft -.wrapped)
wrapped
;;(task +.wrapped)
--