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---
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title: Hoon 101.1: twigs and legs
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sort: 1
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spam: true
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2015-11-13 07:44:57 +03:00
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next: true
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2015-11-03 22:49:57 +03:00
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---
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# Hoon 101.1: twigs and legs
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2015-11-10 22:55:17 +03:00
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In the [last chapter](0-nouns), we learned how to make nouns. In
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this chapter we'll get into Hoon expressions, or *twigs*.
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## How to use this tutorial
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Ideally, you've installed an Urbit planet (if you have a ticket)
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or comet (if you don't). See the [user doc](../../../user).
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We recommend opening up the dojo and just typing the examples;
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you don't know a language until you know it in your fingers.
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Also, make sure you've worked through the chapters in order.
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## Nock for Hoon programmers
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Hoon compiles itself to a pico-interpreter called
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[Nock](../../nock), a combinator algebra defined in 200 words. This
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isn't the place to explain Nock (which relates to Hoon much as
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assembly language relates to C), but Nock is just a way to
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express a function as a noun.
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Nock is a Turing-complete interpreter shaped like (pseudocode):
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```
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Nock(problem) => product
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```
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The `problem` is always a cell `[subject formula]`. The
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function is the `formula`. The input to the function is the
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`subject`. The output is the `product`.
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## From Hoon to Nock
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The Hoon parser turns an source expression (even one as simple as
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`42` from the last chapter) into a noun called a `twig`. If you
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know what an AST is, a twig is an AST. (If you don't know what
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an AST is, it's not necessarily worth the student loans.)
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To simplify slightly, the Hoon compiler is shaped like:
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```
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Hoon(subject-span function-twig) => [product-span formula-nock]
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```
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Hoon, like Nock, is a *subject-oriented* language. Your code is
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always executed against one input noun, the subject. For any
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subject noun in `subject-span` (ie, argument type), the compiler
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produces a Nock formula that computes `function-twig` on that
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subject, and a `product-span` that is the span of the product
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(ie, result type).
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> This is really a nontrivial difference. In a normal,
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non-subject-oriented language, your code executes against a
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scope, stack, environment, or other variable context, probably
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not even a regular user-level value. For ordinary coders,
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"subject-oriented programming" is one of the hardest things to
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understand about Hoon; for some reason, your brain keeps wanting
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the interpreter state to be more interesting.
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## From constants to twigs
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In the last chapter we were entering degenerate twigs like `42`.
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Obviously a numeric constant doesn't use the subject at all, so
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it's not a very interesting example.
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Let's save a test subject as a dojo variable:
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```
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~tasfyn-partyv:dojo> =test [[[8 9] 5] [6 7]]
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```
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The `=test` command tells the dojo to rearrange its stock subject
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to include this `test` noun. Let's check that it's there:
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```
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~tasfyn-partyv:dojo> test
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[[[8 9] 5] 6 7]
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```
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> If you're wondering why `[6 7]` got printed as `6 7`, remember
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that `[]` associates to the right. Also, `=test` is not in any
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way Hoon syntax; it's dojo syntax. Every Hoon twig is a valid
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dojo command, but not vice versa.
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We want to use `test`, this harmless little noun, as the subject
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for some equally harmless twigs. We can do this with the `:`
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syntax, which composes twigs in the functional sense. The twig
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`a:b` uses the product of twig `b` as the subject of twig `a`.
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Trivial cases:
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```
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~tasfyn-partyv:dojo> 42:test
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42
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~tasfyn-partyv:dojo> 42:420
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42
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```
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## Tree addressing
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The simplest twigs produce a subtree, or "leg", of the subject.
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A cell, of course, is a binary tree. The very simplest twig is
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`.`, which produces the root of the tree - the whole subject:
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```
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~tasfyn-partyv:dojo> .:test
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[[[8 9] 5] 6 7]
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```
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Like human languages, Hoon is full of irregular abbreviations.
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The `.` syntax is a shorthand for `+1`:
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```
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~tasfyn-partyv:dojo> +1:test
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[[[8 9] 5] 6 7]
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```
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Hoon has a simple tree addressing scheme (inherited from Nock):
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the root is `1`, the head of `n` is `2n`, the tail is `2n+1`.
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The twig syntax for a tree address is `+n`.
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In our example noun, each leaf is its own tree address:
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```
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~tasfyn-partyv:dojo> +2:test
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[[8 9] 5]
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~tasfyn-partyv:dojo> +3:test
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[6 7]
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~tasfyn-partyv:dojo> +4:test
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[8 9]
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~tasfyn-partyv:dojo> +5:test
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5
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~tasfyn-partyv:dojo> +6:test
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6
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~tasfyn-partyv:dojo> +7:test
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7
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```
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> An instinct for binary tree geometry develops over time as you
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use the system, rather the way most programmers learn to do
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binary math. No, really.
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## Lark syntax
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This alternative syntax for a tree address maps noun geometry
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directly to a glyph. Lark syntax creates a recognizable
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geometric shape by alternating between two head/tail pairs, read
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left to right: `-` and `+`, `<` and `>`.
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Thus `-` is `+2`, `+` is `+3`, `+<` is `+6`, `->` is `+5`, `-<+`
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is `+9`, etc.
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> Why lark syntax? Code full of numbers is ugly and distracting,
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and looks like hardcoded constants. We actually almost never use
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the `+` syntax.
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## Simple faces
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Tree addressing is cool, but it would be pretty tough to program
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in Hoon if it was the only way of getting data out of a subject.
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Let's introduce some new syntax:
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```
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~tasfyn-partyv:dojo> foo=42
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foo=42
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~tasfyn-partyv:dojo> ? foo=42
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foo=@ud
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foo=42
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~tasfyn-partyv:dojo> ?? foo=42
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[%face %foo [%atom %ud]]
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foo=42
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```
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To extend our `++span` mold from the last chapter:
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```
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++ span
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$% [%atom p=@tas]
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[%cell p=span p=span]
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[%cube p=* q=span]
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[%face p=@tas q=span]
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==
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```
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The `%face` span wraps a label around a noun. Then we can
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get a leg by name. Let's make a new dojo variable:
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```
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~tasfyn-partyv:dojo> =test [[[8 9] 5] foo=[6 7]]
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```
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The syntax is what you might expect:
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```
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~tasfyn-partyv:dojo> test
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[[[8 9] 5] foo=[6 7]]
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~tasfyn-partyv:dojo> foo:test
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[6 7]
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```
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Does this do what you expect it to do?
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```
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~tasfyn-partyv:dojo> +3:test
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foo=[6 7]
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~tasfyn-partyv:dojo> ? +3:test
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foo=[@ud @ud]
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foo=[6 7]
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~tasfyn-partyv:dojo> ?? +3:test
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[%face %foo [%cell [%atom %ud] [%atom %ud]]]
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foo=[6 7]
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```
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## Interesting faces; wings
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Let's look at a few more interesting face cases. First, suppose
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we have two cases of `foo`?
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```
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~tasfyn-partyv:dojo> =test [[foo=[8 9] 5] foo=[6 7]]
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~tasfyn-partyv:dojo> foo:test
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[8 9]
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```
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In the tree search, the head wins. We can overcome this with a
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`^` prefix, which tells the search to skip its first hit:
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```
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~tasfyn-partyv:dojo> ^foo:test
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[6 7]
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```
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`^^foo` will skip two foos, `^^^foo` three, *ad infinitum*.
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But what about nested labels?
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```
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~tasfyn-partyv:dojo> =test [[[8 9] 5] foo=[6 bar=7]]
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~tasfyn-partyv:dojo> bar:test
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/~tasfyn-partyv/home/~2015.11.7..21.40.21..1aec:<[1 1].[1 9]>
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-find-limb.bar
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find-none
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```
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We can't search *through* a label. If we want to get our `bar`
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out, we need to search *into* it:
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```
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~tasfyn-partyv:dojo> bar.foo:test
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7
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```
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`bar.foo` is what we call a `wing`, a search path in a noun.
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Note that the wing runs from left to right, ie, the opposite of
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most languages: `bar.foo` means "bar within foo."
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Each step in a wing is a `limb`. (Most languages use metaphors;
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Hoon abuses them.) A limb can be a tree address, like `+3` or
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`.`, or a label like `foo`. We can combine them in one wing:
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```
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~tasfyn-partyv:dojo> bar.foo.+3:test
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7
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```
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It's important to note the difference between `bar.foo:test`
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and `bar:foo:test`, even though they produce the same product:
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```
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~tasfyn-partyv:dojo> bar:foo:test
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7
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```
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`bar.foo` is one twig, which we run on the product of `test`.
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That's different from running `bar` on the product of `foo` on
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the product of `test`.
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> You're probably used to name resolution in variable scopes
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and flat records, but not in trees. Partly this is because the
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tradition in language design is to prefer semantics that make it
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easy to build simple symbol tables, because linear search of a
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nontrivial tree is a bad idea on '80s hardware.
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## Mutation
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Mutation? Well, not really. We can't modify nouns; the concept
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doesn't even make sense in Hoon (or Nock).
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Rather, we build new nouns which are copies of old ones, but
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with mutations. Let's build a "mutated" copy of our test noun:
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```
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~tasfyn-partyv:dojo> test
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[[[8 9] 5] foo=[6 bar=7]]
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~tasfyn-partyv:dojo> test(foo 42)
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[[[8 9] 5] foo=42]
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~tasfyn-partyv:dojo> test(+8 %eight, bar.foo [%hello %world])
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[[[%eight 9] 5] foo=[6 [%hello %world]]]
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```
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As we see, there's no need for the mutant noun to be shaped
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anything like the old noun. They're different nouns.
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A mutation, like `+8 %eight`, specifies a wing and a twig.
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The wing, like `+8` or `bar.foo`, defines a leg to replace.
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The twig runs against the original subject.
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Can we use mutation to build a cyclical noun? Nice try, but no:
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```
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~tasfyn-partyv:dojo> test(+8 test)
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[[[[[[8 9] 5] foo=[6 bar=7]] 9] 5] foo=[6 bar=7]]
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```
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## Progress
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Now, not only can we build a noun, we can get data out of it and
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even evolve new, related nouns. We've still seen only two very
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restricted kinds of twigs: constants and legs. In the [next chapter](2-syntax), we'll actually write some interesting expressions.
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