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---
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title: "Implementing and Verifying \"Static Program Analysis\" in Agda, Part 3: Lattices of Finite Height"
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series: "Static Program Analysis in Agda"
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description: "In this post, I describe the class of finite-height lattices, and prove that lattices we've alread seen are in that class"
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date: 2024-05-30T19:37:01-07:00
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draft: true
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tags: ["Agda", "Programming Languages"]
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---
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In the previous post, I introduced the class of finite-height lattices:
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lattices where chains made from elements and the less-than operator `<`
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can only be so long. As a first example,
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[natural numbers form a lattice]({{< relref "01_spa_agda_lattices#natural-numbers" >}}),
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but they __are not a finite-height lattice__; the following chain can be made
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infinitely long:
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{{< latex >}}
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0 < 1 < 2 < ...
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{{< /latex >}}
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There isn't a "biggest natural number"! On the other hand, we've seen that our
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[sign lattice]({{< relref "01_spa_agda_lattices#sign-lattice" >}}) has a finite
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height; the longest chain we can make is three elements long; I showed one
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such chain (there are many chains of length three) in
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[the previous post]({{< relref "02_spa_agda_combining_lattices#sign-length-three" >}}),
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but here it is again:
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{{< latex >}}
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\bot < + < \top
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{{< /latex >}}
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It's also true that the [Cartesian product lattice \(L_1 \times L_2\)]({{< relref "02_spa_agda_combining_lattices#the-cartesian-product-lattice" >}})
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has a finite height, as long as \(L_1\) and \(L_2\) are themselves finite-height
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lattices. In the specific case where both \(L_1\) and \(L_2\) are the sign
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lattice (\(L_1 = L_2 = \text{Sign} \)) we can observe that the longest
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chains have five elements. The following is one example:
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{{< latex >}}
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(\bot, \bot) < (\bot, +) < (\bot, \top) < (+, \top) < (\top, \top)
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{{< /latex >}}
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The fact that \(L_1\) and \(L_2\) are themselves finite-height lattices is
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important; if either one of them is not, we can easily construct an infinite
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chain of the products. If we allowed \(L_2\) to be natural numbers, we'd
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end up with infinite chains like this one:
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{{< latex >}}
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(\bot, 0) < (\bot, 1) < (\bot, 2) < ...
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{{< /latex >}}
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Another lattice that has a finite height under certain conditions is
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[the map lattice]({{< relref "02_spa_agda_combining_lattices#the-map-lattice" >}}).
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The "under certain conditions" part is important; we can easily construct
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an infinite chain of map lattice elements in general:
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{{< latex >}}
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\{ a : 1 \} < \{ a : 1, b : 1 \} < \{ a: 1, b: 1, c: 1 \} < ...
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{{< /latex >}}
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As long as we have infinite keys to choose from, we can always keep
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adding new keys to make bigger and bigger maps. But if we fix the keys in
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the map -- say, we use only `a` and `b` -- then suddenly our heights are once
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again fixed. In fact, for the two keys I just picked, one longest chain
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is remarkably similar to the product chain above.
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{{< latex >}}
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\{a: \bot, a: \bot\} < \{a: \bot, b: +\} < \{a: \bot, b: \top\} < \{a: +, b: \top\} < \{a: \top, b: \top\}
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{{< /latex >}}
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The class of finite-height lattices is important for static program analysis,
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because it ensures that out our analyses don't take infinite time. Though
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there's an intuitive connection ("finite lattices mean finite execution"),
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the details of why the former is needed for the latter are nuanced. We'll
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talk about them in a subsequent post.
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In the meantime, let's dig deeper into the notion of finite height, and
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the Agda proofs of the properties I've introduced thus far.
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{{< todo >}}
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The rest of this.
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{{< /todo >}}
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