294 lines
16 KiB
Markdown
294 lines
16 KiB
Markdown
---
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title: Compiling a Functional Language Using C++, Part 2 - Parsing
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date: 2019-08-03T01:02:30-07:00
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tags: ["C and C++", "Functional Languages", "Compilers"]
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---
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In the previous post, we covered tokenizing. We learned how to convert an input string into logical segments, and even wrote up a tokenizer to do it according to the rules of our language. Now, it's time to make sense of the tokens, and parse our language.
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### The Theory
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The rules to parse a language are more complicated than the rules for
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recognizing tokens. For instance, consider a simple language of a matching
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number of open and closed parentheses, like `()` and `((()))`. You can't
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write a regular expression for it! We resort to a wider class of languages, called
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__context free languages__. These languages are ones that are matched by __context free grammars__.
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A context free grammar is a list of rules in the form of \\(S \\rightarrow \\alpha\\), where
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\\(S\\) is a __nonterminal__ (conceptualy, a thing that expands into other things), and
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\\(\\alpha\\) is a sequence of nonterminals and terminals (a terminal is a thing that doesn't
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expand into other things; for us, this is a token).
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Let's write a context free grammar (CFG from now on) to match our parenthesis language:
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$$
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\\begin{align}
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S & \\rightarrow ( S ) \\\\\\
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S & \\rightarrow ()
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\\end{align}
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$$
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So, how does this work? We start with a "start symbol" nonterminal, which we usually denote as \\(S\\). Then, to get a desired string,
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we replace a nonterminal with the sequence of terminals and nonterminals on the right of one of its rules. For instance, to get `()`,
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we start with \\(S\\) and replace it with the body of the second one of its rules. This gives us `()` right away. To get `((()))`, we
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have to do a little more work:
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$$
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S \\rightarrow (S) \\rightarrow ((S)) \\rightarrow ((()))
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$$
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In practice, there are many ways of using a CFG to parse a programming language. Various parsing algorithms support various subsets
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of context free languages. For instance, top down parsers follow nearly exactly the structure that we had. They try to parse
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a nonterminal by trying to match each symbol in its body. In the rule \\(S \\rightarrow \\alpha \\beta \\gamma\\), it will
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first try to match \\(\\alpha\\), then \\(\\beta\\), and so on. If one of the three contains a nonterminal, it will attempt to parse
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that nonterminal following the same strategy. However, this leaves a flaw - For instance, consider the grammar
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$$
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\\begin{align}
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S & \\rightarrow Sa \\\\\\
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S & \\rightarrow a
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\\end{align}
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$$
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A top down parser will start with \\(S\\). It will then try the first rule, which starts with \\(S\\). So, dutifully, it will
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try to parse __that__ \\(S\\). And to do that, it will once again try the first rule, and find that it starts with another \\(S\\)...
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This will never end, and the parser will get stuck. A grammar in which a nonterminal can appear in the beginning of one of its rules
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__left recursive__, and top-down parsers aren't able to handle those grammars.
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We __could__ rewrite our grammar without using left-recursion, but we don't want to. Instead, we'll use a __bottom up__ parser,
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using specifically the LALR(1) parsing algorithm. Here's an example of how it works, using our left-recursive grammar. We start with our
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goal string, and a "dot" indicating where we are. At first, the dot is behind all the characters:
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$$
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.aaa
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$$
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We see nothing interesting on the left side of the dot, so we move (or __shift__) the dot forward by one character:
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$$
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a.aa
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$$
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Now, on the left side of the dot, we see something! In particular, we see the body of one of the rules for \\(S\\) (the second one).
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So we __reduce__ the thing on the left side of the dot, by replacing it with the left hand side of the rule (\\(S\\)):
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$$
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S.aa
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$$
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There's nothing else we can do with the left side, so we shift again:
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$$
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Sa.a
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$$
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Great, we see another body on the left of the dot. We reduce it:
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$$
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S.a
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$$
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Just like before, we shift over the dot, and again, we reduce. We end up with our
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start symbol, and nothing on the right of the dot, so we're done!
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### The Practice
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In practice, we don't want to just match a grammar. That would be like saying "yup, this is our language".
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Instead, we want to create something called an __abstract syntax tree__, or AST for short. This tree
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captures the structure of our language, and is easier to work with than its textual representation. The structure
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of the tree we build will often mimic the structure of our grammar: a rule in the form \\(S \\rightarrow A B\\)
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will result in a tree named "S", with two children corresponding the trees built for A and B. Since
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an AST captures the structure of the language, we'll be able to toss away some punctuation
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like `,` and `(`. These tokens will appear in our grammar, but we will tweak our parser to simply throw them away. Additionally,
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we will write our grammar ignoring whitespace, since our tokenizer conveniently throws that into the trash.
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The grammar for arithmetic actually involves more effort than it would appear at first. We want to make sure that our
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parser respects the order of operations. This way, when we have our tree, it will immediately have the structure in
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which multiplication is done before addition. We do this by creating separate "levels" in our grammar, with one
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nonterminal matching addition and subtraction, while another nonterminal matches multiplication and division.
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We want the operation that has the least precedence to be __higher__ in our tree than one of higher precedence.
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For instance, for `3+2*6`, we want our tree to have `+` as the root, `3` as the left child, and the tree for `2*6` as the right child.
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Why? Because this tree represents "the addition of 3 and the result of multiplying 2 by 6". If we had `*` be the root, we'd have
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a tree representing "the multiplication of the result of adding 3 to 2 and 6", which is __not__ what our expression means.
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So, with this in mind, we want our rule for __addition__ (represented with the nonterminal \\(A\_{add}\\), to be matched first, and
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for its children to be trees created by the multiplication rule, \\(A\_{mult}\\). So we write the following rules:
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$$
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\\begin{align}
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A\_{add} & \\rightarrow A\_{add}+A\_{mult} \\\\\\
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A\_{add} & \\rightarrow A\_{add}-A\_{mult} \\\\\\
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A\_{add} & \\rightarrow A\_{mult}
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\\end{align}
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$$
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The first rule matches another addition, added to the result of a multiplication. Similarly, the second rule matches another addition, from which the result of a multiplication is then subtracted. We use the \\(A\_{add}\\) on the left side of \\(+\\) and \\(-\\) in the body
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because we want to be able to parse strings like `1+2+3+4`, which we want to view as `((1+2)+3)+4` (mostly because
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subtraction is [left-associative](https://en.wikipedia.org/wiki/Operator_associativity)). So, we want the top level
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of the tree to be the rightmost `+` or `-`, since that means it will be the "last" operation. You may be asking,
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> You define addition in terms of addition; how will parsing end? What if there's no addition at all, like `2*6`?
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This is the purpose of the third rule, which serves to say "an addition expression can just be a multiplication,
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without any plusses or minuses." Our rules for multiplication are very similar:
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$$
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\\begin{align}
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A\_{mult} & \\rightarrow A\_{mult}*P \\\\\\
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A\_{mult} & \\rightarrow A\_{mult}/P \\\\\\
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A\_{mult} & \\rightarrow P
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\\end{align}
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$$
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P, in this case, is an a__p__lication (remember, application has higher precedence than any binary operator).
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Once again, if there's no `*` or `\`, we simply fall through to a \\(P\\) nonterminal, representing application.
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Application is refreshingly simple:
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$$
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\\begin{align}
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P & \\rightarrow P B \\\\\\
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P & \\rightarrow B
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\\end{align}
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$$
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An application is either only one "thing" (represented with \\(B\\), for __b__ase), such as a number or an identifier,
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or another application followed by a thing.
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We now need to define what a "thing" is. As we said before, it's a number, or an identifier. We also make a parenthesized
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arithmetic expression a "thing", allowing us to wrap right back around and recognize anything inside parentheses:
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$$
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\\begin{align}
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B & \\rightarrow \text{num} \\\\\\
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B & \\rightarrow \text{lowerVar} \\\\\\
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B & \\rightarrow \text{upperVar} \\\\\\
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B & \\rightarrow ( A\_{add} ) \\\\\\
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B & \\rightarrow C
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\\end{align}
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$$
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What's the last \\(C\\)? We also want a "thing" to be a case expression. Here are the rules for that:
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$$
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\\begin{align}
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C & \\rightarrow \\text{case} \\; A\_{add} \\; \\text{of} \\; \\{ L\_B\\} \\\\\\
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L\_B & \\rightarrow R \\; L\_B \\\\\\
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L\_B & \\rightarrow R \\\\\\
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R & \\rightarrow N \\; \\text{arrow} \\; \\{ A\_{add} \\} \\\\\\
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N & \\rightarrow \\text{lowerVar} \\\\\\
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N & \\rightarrow \\text{upperVar} \\; L\_L \\\\\\
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L\_L & \\rightarrow \\text{lowerVar} \\; L\_L \\\\\\
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L\_L & \\rightarrow \\epsilon
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\\end{align}
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$$
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\\(L\_B\\) is the list of branches in our case expression. \\(R\\) is a single branch, which is in the
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form `Pattern -> Expression`. \\(N\\) is a pattern, which we will for now define to be either a variable name
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(\\(\\text{lowerVar}\\)), or a constructor with some arguments. The arguments of a constructor will be
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lowercase names, and a list of those arguments will be represented with \\(L\_L\\). One of the bodies
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of this nonterminal is just the character \\(\\epsilon\\), which just means "nothing".
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We use this because a constructor can have no arguments (like Nil).
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We can use these grammar rules to represent any expression we want. For instance, let's try `3+(multiply 2 6)`,
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where multiply is a function that, well, multiplies. We start with \\(A_{add}\\):
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$$
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\\begin{align}
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& A\_{add} \\\\\\
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& \\rightarrow A\_{add} + A\_{mult} \\\\\\
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& \\rightarrow A\_{mult} + A\_{mult} \\\\\\
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& \\rightarrow P + A\_{mult} \\\\\\
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& \\rightarrow B + A\_{mult} \\\\\\
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& \\rightarrow \\text{num(3)} + A\_{mult} \\\\\\
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& \\rightarrow \\text{num(3)} + P \\\\\\
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& \\rightarrow \\text{num(3)} + B \\\\\\
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& \\rightarrow \\text{num(3)} + (A\_{add}) \\\\\\
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& \\rightarrow \\text{num(3)} + (A\_{mult}) \\\\\\
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& \\rightarrow \\text{num(3)} + (P) \\\\\\
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& \\rightarrow \\text{num(3)} + (P \\; \\text{num(6)}) \\\\\\
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& \\rightarrow \\text{num(3)} + (P \\; \\text{num(2)} \\; \\text{num(6)}) \\\\\\
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& \\rightarrow \\text{num(3)} + (\\text{lowerVar(multiply)} \\; \\text{num(2)} \\; \\text{num(6)}) \\\\\\
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\\end{align}
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$$
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We're almost there. We now want a rule for a "something that can appear at the top level of a program", like
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a function or data type declaration. We make a new set of rules:
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$$
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\\begin{align}
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T & \\rightarrow \\text{defn} \\; \\text{lowerVar} \\; L\_P =\\{ A\_{add} \\} \\\\\\
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T & \\rightarrow \\text{data} \\; \\text{upperVar} = \\{ L\_D \\} \\\\\\
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L\_D & \\rightarrow D \\; , \\; L\_D \\\\\\
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L\_D & \\rightarrow D \\\\\\
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L\_P & \\rightarrow \\text{lowerVar} \\; L\_P \\\\\\
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L\_P & \\rightarrow \\epsilon \\\\\\
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D & \\rightarrow \\text{upperVar} \\; L\_U \\\\\\
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L\_U & \\rightarrow \\text{upperVar} \\; L\_U \\\\\\
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L\_U & \\rightarrow \\epsilon
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\\end{align}
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$$
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That's a lot of rules! \\(T\\) is the "top-level declaration rule. It matches either
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a function or a data definition. A function definition consists of the keyword "defn",
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followed by a function name (starting with a lowercase letter), followed by a list of
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parameters, represented by \\(L\_P\\).
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A data type definition consists of the name of the data type (starting with an uppercase letter),
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and a list \\(L\_D\\) of data constructors \\(D\\). There must be at least one data constructor in this list,
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so we don't use the empty string rule here. A data constructor is simply an uppercase variable representing
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a constructor of the data type, followed by a list \\(L\_U\\) of zero or more uppercase variables (representing
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the types of the arguments of the constructor).
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Finally, we want one or more of these declarations in a valid program:
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$$
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\\begin{align}
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G & \\rightarrow T \\; G \\\\\\
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G & \\rightarrow T
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\\end{align}
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$$
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Just like with tokenizing, there exists a piece of software that will generate a bottom-up parser for us, given our grammar.
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It's called Bison, and it is frequently used with Flex. Before we get to bison, though, we need to pay a debt we've already
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incurred - the implementation of our AST. Such a tree is language-specific, so Bison doesn't generate it for us. Here's what
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I came up with:
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{{< codeblock "C++" "compiler/02/ast.hpp" >}}
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We create a base class for an expression tree, which we call `ast`. Then, for each possible syntactic construct in our language
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(a number, a variable, a binary operation, a case expression) we create a subclass of `ast`. The `ast_case` subclass
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is the most complex, since it must contain a list of case expression branches, which are a combination of a `pattern` and
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another expression.
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Finally, we get to writing our Bison file, `parser.y`. Here's what I come up with:
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{{< rawblock "compiler/02/parser.y" >}}
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There's a few things to note here. First of all, the __parser__ is the "source of truth" regarding what tokens exist in our language.
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We have a list of `%token` declarations, each of which corresponds to a regular expression in our scanner.
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Next, observe that there's
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a certain symmetry between our parser and our scanner. In our scanner, we mixed the theoretical idea of a regular expression
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with an __action__, a C++ code snippet to be executed when a regular expression is matched. This same idea is present
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in the parser, too. Each rule can produce a value, which we call a __semantic value__. For type safety, we allow
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each nonterminal and terminal to produce only one type of semantic value. For instance, all rules for \\(A_{add}\\) must
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produce an expression. We specify the type of each nonterminal and using `%type` directives. The types of terminals
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are specified when they're declared.
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Next, we must recognize that Bison was originally made for C, rather than C++. In order to allow the parser
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to store and operate on semantic values of various types, the canonical solution back in those times was to
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use a C `union`. Unions are great, but for C++, they're more trouble than they're worth: unions don't
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allow for non-trivial constructors! This means that stuff like `std::unique_ptr` and `std::string` is off limits as
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a semantic value. But we'd really much rather use them! The solution is to:
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1. Specify the language to be C++, rather than C.
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2. Enable the `variant` API feature, which uses a lightweight `std::variant` alternative in place of a union.
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3. Enable the creation of token constructors, which we will use in Flex.
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In order to be able to use the variant-based API, we also need to change the Flex `yylex` function
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to return `yy::parser::symbol_type`. You can see it in our forward declaration of `yylex`.
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Now that we made these changes, it's time to hook up Flex to all this. Here's a new version
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of the Flex scanner, with all necessary modifications:
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{{< rawblock "compiler/02/scanner.l" >}}
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The key two ideas are that we overrode the default signature of `yylex` by changing the
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`YY_DECL` preprocessor variable, and used the `yy::parser::make_<TOKEN>` functions
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to return the `symbol_type` rather than `int`.
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Finally, let's get a main function so that we can at least check for segmentation faults
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and other obvious mistakes:
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{{< codeblock "C++" "compiler/02/main.cpp" >}}
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Now, we can compile and run the code:
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{{< codeblock "Bash" "compiler/02/compile.sh" >}}
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We used the `-d` option for Bison to generate the `compiler_parser.hpp` header file,
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which exports our token declarations and token creation functions, allowing
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us to use them in Flex.
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At last, we can feed some code to the parser from `stdin`. Let's try it:
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```
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./a.out
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defn main = { add 320 6 }
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defn add x y = { x + y }
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```
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The program prints `2`, indicating two declarations were made. Let's try something obviously
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wrong:
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```
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./a.out
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}{
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```
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We are told an error occured. Excellent! We're not really sure what our tree looks like, though.
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We just know there's __stuff__ in the list of definitions. Having read our source code into
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a structure we're more equipped to handle, we can now try to verify that the code
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makes sense in [Part 3 - Type Checking]({{< relref "03_compiler_typechecking.md" >}}).
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