mirror of
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325 lines
9.9 KiB
Plaintext
325 lines
9.9 KiB
Plaintext
::
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:::: /hoon/metal/gen
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::
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/? 310
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/+ old-zuse
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=, old-zuse
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::
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::::
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!:
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:- %say
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|= $: {now/@da * bec/beak}
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{{who/@p ~} try/_| ~}
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==
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::
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:: we're creating an event series E whose lifecycle can be computed
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:: with the urbit lifecycle formula L, `[2 [0 3] [0 2]]`. that is:
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:: if E is the list of events processed by a computer in its life,
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:: its final state is S, where S is nock(E L).
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::
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:: in practice, the first five nouns in E are: two boot formulas,
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:: a hoon compiler as a nock formula, the same compiler as source,
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:: and the arvo kernel as source.
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::
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:: after the first five special events, we enter an iterative
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:: sequence of regular events which continues for the rest of the
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:: computer's life. during this sequence, each state is a function
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:: that, passed the next event, produces the next state.
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::
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:: each event is a `[date wire type data]` tuple, where `date` is a
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:: 128-bit Urbit date; `wire` is an opaque path which output can
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:: match to track causality; `type` is a symbol describing the type
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:: of input; and `data` is input data specific to `type`.
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::
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:: in real life we don't actually run the lifecycle loop,
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:: since real life is updated incrementally and also cares
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:: about things like output. we couple to the internal
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:: structure of the state machine and work directly with
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:: the underlying arvo engine.
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::
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:: this arvo core, which is at `+7` (Lisp `cddr`) of the state
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:: function (see its public interface in `sys/arvo`), gives us
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:: extra features, like output, which are relevant to running
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:: a real-life urbit vm, but don't affect the formal definition.
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::
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:: so a real-life urbit interpreter is coupled to the shape of
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:: the arvo core. it becomes very hard to change this shape.
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:: fortunately, it is not a very complex interface.
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::
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:- %noun
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::
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:: boot-one: lifecycle formula
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::
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=+ ^= boot-one
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::
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:: event 1 is the lifecycle formula which computes the final
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:: state from the full event sequence.
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::
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:: the formal urbit state is always just a gate (function)
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:: which, passed the next event, produces the next state.
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::
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=> [boot-formula=* full-sequence=*]
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!= ::
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:: first we use the boot formula (event 1) to set up
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:: the pair of state function and main sequence. the boot
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:: formula peels off the first n (currently 3) events
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:: to set up the lifecycle loop.
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::
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=+ [state-gate main-sequence]=.*(full-sequence boot-formula)
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::
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:: in this lifecycle loop, we replace the state function
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:: with its product, called on the next event, until
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:: we run out of events.
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::
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|- ?@ main-sequence
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state-gate
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%= $
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main-sequence +.main-sequence
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state-gate .*(state-gate(+< -.main-sequence) -.state-gate)
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==
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::
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:: boot-two: startup formula
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::
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=+ ^= boot-two
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::
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:: event 2 is the startup formula, which verifies the compiler
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:: and starts the main lifecycle.
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::
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=> :* :: event 3: a formula producing the hoon compiler
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::
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compiler-formula=**
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::
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:: event 4: hoon compiler source, compiling to event 2
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::
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compiler-source=*@t
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::
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:: event 5: arvo kernel source
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::
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arvo-source=*@t
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::
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:: events 6..n: main sequence with normal semantics
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::
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main-sequence=**
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==
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!= :_ main-sequence
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::
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:: activate the compiler gate. the product of this formula
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:: is smaller than the formula. so you might think we should
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:: save the gate itself rather than the formula producing it.
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:: but we have to run the formula at runtime, to register jets.
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::
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:: as always, we have to use raw nock as we have no type.
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:: the gate is in fact ++ride.
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::
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~> %slog.[0 leaf+"1-b"]
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=+ ^= compiler-gate
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.*(0 compiler-formula)
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::
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:: compile the compiler source, producing (pair span nock).
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:: the compiler ignores its input so we use a trivial span.
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::
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~> %slog.[0 leaf+"1-c"]
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=+ ^= compiler-tool
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.*(compiler-gate(+< [%noun compiler-source]) -.compiler-gate)
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::
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:: switch to the second-generation compiler. we want to be
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:: able to generate matching reflection nouns even if the
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:: language changes -- the first-generation formula will
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:: generate last-generation spans for `!>`, etc.
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::
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~> %slog.[0 leaf+"1-d"]
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=. compiler-gate .*(0 +:compiler-tool)
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::
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:: get the span (type) of the kernel core, which is the context
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:: of the compiler gate. we just compiled the compiler,
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:: so we know the span (type) of the compiler gate. its
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:: context is at tree address `+>` (ie, `+7` or Lisp `cddr`).
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:: we use the compiler again to infer this trivial program.
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::
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~> %slog.[0 leaf+"1-e"]
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=+ ^= kernel-span
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-:.*(compiler-gate(+< [-.compiler-tool '+>']) -.compiler-gate)
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::
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:: compile the arvo source against the kernel core.
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::
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~> %slog.[0 leaf+"1-f"]
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=+ ^= kernel-tool
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.*(compiler-gate(+< [kernel-span arvo-source]) -.compiler-gate)
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::
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:: create the arvo kernel, whose subject is the kernel core.
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::
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~> %slog.[0 leaf+"1-g"]
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.*(+>:compiler-gate +:kernel-tool)
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::
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:: sys: root path to boot system, `/~me/[desk]/now/sys`
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::
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=+ sys=`path`/(scot %p p.bec)/[q.bec]/(scot %da now)/sys
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::
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:: compiler-source: hoon source file producing compiler, `sys/hoon`
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::
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=+ compiler-source=.^(@t %cx (welp sys /hoon/hoon))
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::
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:: compiler-twig: compiler as hoon expression
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::
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~& %metal-parsing
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=+ compiler-twig=(ream compiler-source)
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~& %metal-parsed
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::
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:: compiler-formula: compiler as nock formula
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::
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~& %metal-compiling
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=+ compiler-formula=q:(~(mint ut %noun) %noun compiler-twig)
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~& %metal-compiled
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::
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:: arvo-source: hoon source file producing arvo kernel, `sys/arvo`
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::
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=+ arvo-source=.^(@t %cx (welp sys /arvo/hoon))
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::
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:: main-moves: installation actions
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::
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=+ ^= main-moves
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|^ ^- (list ovum)
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:~ ::
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:: configure identity
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::
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[[%name (scot %p who) ~] [%veal who]]
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::
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:: sys/zuse: standard library
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::
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(vent %$ /zuse)
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::
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:: sys/vane/ames: network
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::
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(vent %a /vane/ames)
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::
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:: sys/vane/behn: timer
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::
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(vent %b /vane/behn)
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::
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:: sys/vane/clay: revision control
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::
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(vent %c /vane/clay)
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::
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:: sys/vane/dill: console
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::
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(vent %d /vane/dill)
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::
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:: sys/vane/eyre: web
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::
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(vent %e /vane/eyre)
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::
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:: sys/vane/ford: build
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::
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(vent %f /vane/ford)
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::
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:: sys/vane/gall: applications
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::
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(vent %g /vane/gall)
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::
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:: sys/vane/jael: security
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::
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(vent %j /vane/jael)
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::
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:: legacy boot event
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::
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[[%$ %term '1' ~] [%boot %sith who `@uw`who &]]
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::
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:: userspace:
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::
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:: /app %gall applications
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:: /gen :dojo generators
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:: /lib %ford libraries
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:: /mar %ford marks
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:: /sur %ford structures
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:: /ren %ford renderers
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:: /web %eyre web content
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:: /sys system files
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::
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(user /app /gen /lib /mar /ren /sec /sur /sys /web ~)
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==
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:: ::
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++ user :: userspace loading
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|= :: sal: all spurs to load from
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::
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sal/(list spur)
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^- ovum
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::
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:: hav: all user files
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::
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=; hav ~& user-files+(lent hav)
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[[%$ %sync ~] [%into %$ & hav]]
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=| hav/mode:clay
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|- ^+ hav
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?~ sal ~
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=. hav $(sal t.sal)
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::
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:: tyl: spur
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::
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=/ tyl i.sal
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|- ^+ hav
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::
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:: pax: full path at `tyl`
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:: lon: directory at `tyl`
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::
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=/ pax (en-beam:format bec tyl)
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=/ lon .^(arch %cy pax)
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=? hav ?=(^ fil.lon)
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?. ?=({$hoon *} tyl)
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::
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:: install only hoon files for now
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::
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hav
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::
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:: cot: file as plain-text octet-stream
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::
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=; cot [[(flop `path`tyl) `[/text/plain cot]] hav]
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^- octs
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?- tyl
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{$hoon *}
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=/ dat .^(@t %cx pax)
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[(met 3 dat) dat]
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==
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=/ all ~(tap by dir.lon)
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|- ^- mode:clay
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?~ all hav
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$(all t.all, hav ^$(tyl [p.i.all tyl]))
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::
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++ vent
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|= {abr/term den/path}
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=+ pax=(weld sys den)
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=+ txt=.^(@ %cx (welp pax /hoon))
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`ovum`[[%vane den] [%veer abr pax txt]]
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--
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::
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:: main-events: full events with advancing times
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::
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=. now ~2017.3.1
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=+ ^= main-events
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|- ^- (list (pair @da ovum))
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?~ main-moves ~
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:- [now i.main-moves]
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$(main-moves t.main-moves, now (add now (bex 48)))
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::
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~? try
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~& %metal-testing
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=+ ^= yop
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^- @p
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%- mug
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.* :* boot-one
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boot-two
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compiler-formula
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compiler-source
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arvo-source
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main-events
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==
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[2 [0 3] [0 2]]
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[%metal-tested yop]
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::
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:* boot-one
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boot-two
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compiler-formula
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compiler-source
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arvo-source
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main-events
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==
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