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| title | series | description | date | tags | draft | ||
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| Implementing and Verifying "Static Program Analysis" in Agda, Part 6: Control Flow Graphs | Static Program Analysis in Agda | In this post, I show how I show an Agda definition of control flow graph building | 2024-11-13T17:32:42-07:00 |
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In the previous section, I've given a formal definition of the programming language that I've been trying to analyze. This formal definition serves as the "ground truth" for how our little imperative programs are executed; however, program analyses (especially in practice) seldom take the formal semantics as input. Instead, they focus on more pragmatic program representations from the world of compilers. One such representation are Control Flow Graphs (CFGs). That's what I want to discuss in this post.
Let's start by building some informal intuition. CFGs are pretty much what their name suggests: they are a type of graph; their edges show how execution might jump from one piece of code to another (how control might flow).
For example, take the below program.
x = ...;
if x {
x = 1;
} else {
x = 0;
}
y = x;
The CFG might look like this:
{{< figure src="if-cfg.png" label="CFG for simple if-else code." class="small" >}}
Here, the initialization of x with ..., as well as the if condition (just x),
are guaranteed to execute one after another, so they occupy a single node. From there,
depending on the condition, the control flow can jump to one of the
branches of the if statement: the "then" branch if the condition is truthy,
and the "else" branch if the condition is falsy. As a result, there are two
arrows coming out of the initial node. Once either branch is executed, control
always jumps to the code right after the if statement (the y = x). Thus,
both the x = 1 and x = 0 nodes have a single arrow to the y = x node.
As another example, if you had a loop:
x = ...;
while x {
x = x - 1;
}
y = x;
The CFG would look like this:
{{< figure src="while-cfg.png" label="CFG for simple while code." class="small" >}}
Here, the condition of the loop (x) is not always guaranteed to execute together
with the code that initializes x. That's because the condition of the loop
is checked after every iteration, whereas the code before the loop is executed
only once. As a result, x = ... and x occupy distinct CFG nodes. From there,
the control flow can proceed in two different ways, depending on the value
of x. If x is truthy, the program will proceed to the loop body (decrementing x).
If x is falsy, the program will skip the loop body altogether, and go to the
code right after the loop (y = x). This is indicated by the two arrows
going out of the x node. After executing the body, we return to the condition
of the loop to see if we need to run another iteration. Because of this, the
decrementing node has an arrow back to the loop condition.
Now, let's be a bit more precise. Control Flow Graphs are defined as follows:
-
The nodes are basic blocks. Paraphrasing Wikipedia's definition, a basic block is a piece of code that has only one entry point and one exit point.
The one-entry-point rule means that it's not possible to jump into the middle of the basic block, executing only half of its instructions. The execution of a basic block always begins at the top. Symmetrically, the one-exit-point rule means that you can't jump away to other code, skipping some instructions. The execution of a basic block always ends at the bottom.
As a result of these constraints, when running a basic block, you are guaranteed to execute every instruction in exactly the order they occur in, and execute each instruction exactly once.
-
The edges are jumps between basic blocks. We've already seen how
ifandwhilestatements introduce these jumps.
Basic blocks can only be made of code that doesn't jump (otherwise, we violate the single-exit-point policy). In the previous post, we defined exactly this kind of code as [simple statements]({{< relref "05_spa_agda_semantics#introduce-simple-statements" >}}). So, in our control flow graph, nodes will be sequences of simple statements. {#list-basic-stmts}
Control Flow Graphs in Agda
Basic Definition
At an abstract level, it's easy to say "it's just a graph where X is Y" about
anything. It's much harder to give a precise definition of such a graph,
particularly if you want to rule out invalid graphs (e.g., ones with edges
pointing nowhere). In Agda, I chose the represent a CFG with two lists: one of nodes,
and one of edges. Each node is simply a list of BasicStmts, as
I described in a preceding paragraph. An edge is simply a pair of numbers,
each number encoding the index of the node connected by the edge.
Here's where it gets a little complicated. I don't want to use plain natural
numbers for indices, because that means you can easily introduce "broken" edge.
For example, what if you have 4 nodes, and you have an edge (5, 5)? Therefore,
I picked the finite natural numbers represented by Fin.
data Fin : ℕ → Set where
zero : Fin (suc n)
suc : (i : Fin n) → Fin (suc n)
Specifically, Fin n is the type of natural numbers less than n. Following
this definition, Fin 3 represents the numbers 0, 1 and 2. These are
represented using the same constructors as Nat: zero and suc. The type
of zero is Fin (suc n) for any n; this makes sense because zero is less
than any number plus one. For suc, the bound n of the input i is incremented
by one, leading to another suc n in the final type. This makes sense because if
i < n, then i + 1 < n + 1. I've previously explained this data type
[in another post on this site]({{< relref "01_aoc_coq#aside-vectors-and-finite-mathbbn" >}}).
Here's my definition of Graphs written using Fin:
{{< codelines "Agda" "agda-spa/Language/Graphs.agda" 24 39 >}}
I explicitly used a size field, which determines how many nodes are in the
graph, and serves as the upper bound for the edge indices. From there, an
index Index into the node list is
{{< sidenote "right" "size-note" "just a natural number less than size," >}}
Ther are size natural numbers less than size:
0, 1, ..., size - 1.
{{< /sidenote >}}
and an edge is just a pair of indices. The graph then contains a vector
(exact-length list) nodes of all the basic blocks, and then a list of
edges edges.
There are two fields here that I have not yet said anything about: inputs
and outputs. When we have a complete CFG for our programs, these fields are
totally unnecessary. However, as we are building the CFG, these will come
in handy, by telling us how to stitch together smaller sub-graphs that we've
already built. Let's talk about that next.
Combining Graphs
Suppose you're building a CFG for a program in the following form:
code1;
code2;
Where code1 and code2 are arbitrary pieces of code, which could include
statements, loops, and pretty much anything else. Besides the fact that they
occur one after another, these pieces of code are unrelated, and we can
build CFGs for each one them independently. However, the fact that code1 and
code2 are in sequence means that the full control flow graph for the above
program should have edges going from the nodes in code1 to the nodes in code2.
Of course, not every node in code1 should have such edges: that would
mean that after executing any "basic" sequence of instructions, you could suddenly
decide to skip the rest of code1 and move on to executing code2.
Thus, we need to be more precise about what edges we need to insert; we want
to insert edges between the "final" nodes in code1 (where control ends up
after code1 is finished executing) and the "initial" nodes in code2 (where
control would begin once we started executing code2). Those are the outputs
and inputs, respectively. When stitching together sequenced control graphs,
we will connect each of the outputs of one to each of the inputs of the other.
This is defined by the operation g₁ ↦ g₂, which sequences two graphs g₁ and g₂:
{{< codelines "Agda" "agda-spa/Language/Graphs.agda" 72 83 >}}
The definition starts out pretty innocuous, but gets a bit complicated by the
end. The sum of the numbers of nodes in the two operands becomes the new graph
size, and the nodes from the two graphs are all included in the result. Then,
the definitions start making use of various operators like ↑ˡᵉ and ↑ʳᵉ;
these deserve an explanation.
The tricky thing is that when we're concatenating lists of nodes, we are changing
some of the indices of the elements within. For instance, in the lists
[x] and [y], the indices of both x and y are 0; however, in the
concatenated list [x, y], the index of x is still 0, but the index of y
is 1. More generally, when we concatenate two lists l1 and l2, the indices
into l1 remain unchanged, whereas the indices l2 are shifted length l2.
Actually, that's not all there is to it. The values of the indices into
the left list don't change, but their types do! They start as Fin (length l1),
but for the whole list, these same indices will have type Fin (length l1 + length l2)).
To help deal with this, Agda provides the operators
↑ˡ
and ↑ʳ
that implement this re-indexing and re-typing. The former implements "re-indexing
on the left" -- given an index into the left list l1, it changes its type
by adding the other list's length to it, but keeps the index value itself
unchanged. The latter implements "re-indexing on the right" -- given an index
into the right list l2, it adds the length of the first list to it (shifting it),
and does the same to its type.
The definition leads to the following equations:
l1 : Vec A n
l2 : Vec A m
idx1 : Fin n -- index into l1
idx2 : Fin m -- index into l2
l1 [ idx1 ] ≡ (l1 ++ l2) [ idx1 ↑ˡ m ]
l2 [ idx2 ] ≡ (l1 ++ l2) [ n ↑ʳ idx2 ]
The operators used in the definition above are just versions of the same
re-indexing operators. The ↑ˡᵉ operator applies ↑ˡ to all the (e)dges
in a graph, and the ↑ˡi applies it to all the (i)ndices in a list
(like inputs and outputs).
Given these definitions, hopefully the intent with the rest of the definition
is not too hard to see. The edges in the new graph come from three places:
the graph g₁ and g₂, and from creating a new edge from each of the outputs
of g₁ to each of the inputs of g₂. We keep the inputs of g₁ as the
inputs of the whole graph (since g₁ comes first), and symmetrically we keep
the outputs of g₂. Of course, we do have to re-index them to keep them
pointing at the right nodes.
Another operation we will need is "overlaying" two graphs: this will be like
placing them in parallel, without adding jumps between the two. We use this
operation when combining the sub-CFGs of the "if" and "else" branches of an
if/else, which both follow the condition, and both proceed to the code after
the conditional.
{{< codelines "Agda" "agda-spa/Language/Graphs.agda" 59 70 >}}
Everything here is just concatenation; we pool together the nodes, edges, inputs, and outputs, and the main source of complexity is the re-indexing.
The one last operation, which we will use for while loops, is looping. This
operation simply connects the outputs of a graph back to its inputs (allowing
looping), and also allows the body to be skipped. This is slightly different
from the graph for while loops I showed above; the reason for that is that
I currently don't include the conditional expressions in my CFG. This is a
limitation that I will address in future work.
{{< codelines "Agda" "agda-spa/Language/Graphs.agda" 85 95 >}}
Given these thee operations, I construct Control Flow Graphs as follows, where
singleton creates a new CFG node with the given list of simple statements:
{{< codelines "Agda" "agda-spa/Language/Graphs.agda" 122 126 >}}
Throughout this, I've been liberal to include empty CFG nodes as was convenient. This is a departure from the formal definition I gave above, but it makes things much simpler.
Additional Functions
To integrate Control Flow Graphs into our lattice-based program analyses, we'll need to do a couple of things. First, upon reading the reference Static Program Analysis text, one sees a lot of quantification over the predecessors or successors of a given CFG node. For example, the following equation is from Chapter 5:
{{< latex >}} \textit{JOIN}(v) = \bigsqcup_{w \in \textit{pred}(v)} \llbracket w \rrbracket {{< /latex >}}
To compute the \textit{JOIN} function (which we have not covered yet) for
a given CFG node, we need to iterate over all of its predecessors, and
combine their static information using \sqcup, which I first
[explained several posts ago]({{< relref "01_spa_agda_lattices#least-upper-bound" >}}).
To be able to iterate over them, we need to be able to retrieve the predecessors
of a node from a graph!
Our encoding does not make computing the predecessors particularly easy; to
check if two nodes are connected, we need to check if an Index-Index pair
corresponding to the nodes is present in the edges list. To this end, we need
to be able to compare edges for equality. Fortunately, it's relatively
straightforward to show that our edges can be compared in such a way;
after all, they are just pairs of Fins, and Fins and products support
these comparisons.
{{< codelines "Agda" "agda-spa/Language/Graphs.agda" 149 152 >}}
Next, if we can compare edges for equality, we can check if an edge is in a list. Agda provides a built-in function for this:
{{< codelines "Agda" "agda-spa/Language/Graphs.agda" 154 154 >}}
To find the predecessors of a particular node, we go through all other nodes in the graph and see if there's an edge there between those nodes and the current one. This is preferable to simply iterating over the edges because we may have duplicates in that list (why not?).
{{< codelines "Agda" "agda-spa/Language/Graphs.agda" 165 166 >}}
{{< todo >}} the rest {{< /todo >}}