34 KiB
3 Parser
In this chapter I'll show how I would make a parser.
A parser, in addition to our lexer, transforms the input program as text, meaning an unstructured sequence of characters, into a structered representation. Structured meaning the representation tells us about the different constructs such as if statements and expressions.
3.1 Abstract Syntax Tree AST
The result of parsing is a tree structure representing the input program.
This structure is a recursive structure storing the different parts of the program.
This is how I would define an AST data type.
type Stmt = {
kind: StmtKind,
pos: Pos,
id: number,
};
type StmtKind =
| { type: "error" }
// ...
| { type: "let", ident: string, value: Expr }
// ...
;
type Expr = {
kind: ExprKind,
pos: Pos,
id: number,
};
type ExprKind =
| { type: "error" }
// ...
| { type: "int", value: number }
// ...
;
Both Stmt
(statement) and Expr
(expression) are polymorphic types, meaning an expression, for example, can be either an addition operation containing 2 inner expressions or an integer expression containing the integer value, etc. This can also be implemented with classes and sub classes.
For both Stmt
and Expr
there's an error-kind. This makes the parser simpler, as we won't need to manage parsing failures differently than successful parslings.
Both AST node types contain an id
field. This field will be a unique value for each instance of a node.
3.2 The parser class
3.2.1 Consumer of lexer
To start, we'll implement a Parser
class, which for now is simply a consumer of a token iterater, meaning the lexer. In simple terms, whereas the lexer is a transformation from text to tokens, the parser is a transformation from token to an AST, except that the parser is not an iterator.
class Parser {
private currentToken: Token | null;
public constructor(private lexer: Lexer) {
this.currentToken = lexer.next();
}
// ...
private step() { this.currentToken = this.lexer.next() }
private done(): bool { return this.currentToken == null; }
private current(): Token { return this.currentToken!; }
// ...
}
This implementation should look familiar compared to the lexer. We use the currentToken
as a 'buffer', and then just use the .next()
on the lexer
.
Just as the lexer, we'll have a .pos()
method, returning the current position.
For convenience, although there are other ways of doing it, we'll implement another public method on Lexer
, which will return the lexer's current position.
class Lexer {
// ...
public currentPos(): Pos { return this.pos(); }
// ...
}
The reason, is that when the lexer has reached the end of the file, the .next()
method will return null
instead of a token with a position, meaning we won't get the position after the last token.
class Parser {
// ...
private pos(): Pos {
if (this.done())
return this.lexer.currentPos();
return this.current().pos;
}
// ...
}
The parser does not need to keep track of index
, line
and col
as those are stored in the tokens. The token's position is preferred to the lexer's.
Also like the lexer, we'll have a .test()
method in the parser, which will test for token type rather than strings or regex.
class Parser {
// ...
private test(type: string): bool {
return !this.done() && this.current().type === type;
}
// ...
}
When testing, we first check that we have not reach the end. Either we have to do that here, or the caller will have to write something like !this.done() && this.test(...)
, and it's easy to do it here.
3.2.2 Reporting errors
We'll want a method for reporting errors.
class Parser {
// ...
private report(msg: string, pos = this.pos()) {
console.log(`Parser: ${msg} at ${pos.line}:${pos.col}`);
}
// ...
}
3.2.3 Constructing AST nodes
We also want methods for constructing statements and expressions with auto incrementing ids.
class Parser {
// ...
private nextNodeId = 0;
// ...
private stmt(kind: StmtKind, pos: Pos): Stmt {
const id = this.nextNodeId;
this.nextNodeId += 1;
return { kind, pos, id };
}
private expr(kind: ExprKind, pos: Pos): Expr {
const id = this.nextNodeId;
this.nextNodeId += 1;
return { kind, pos, id };
}
// ...
}
3.3 Operands
Operands are the individual parts of an operation. For example, in the math expression a + b
, (would be + a b
in the input language), a
and b
are the operands, while +
is the operator. In the expression a + b * c
, the operands are a
, b
and c
. But in the expression a * (b + c)
, the operands of the multiply operation are a
and (b + c)
. (b + c)
is a singular operand, because it is enclosed on both sides. This is how we'll define operands.
We'll make a public method in Parser
called parseOperand
.
class Parser {
// ...
public parseOperand(): Expr {
const pos = this.pos();
// ...
this.report("expected expr", pos);
this.step();
return this.expr({ type: "error" }, pos);
}
// ...
}
3.3.1 Identifiers and literals
Identifiers and literals (integers, strings) are single token constructs, meaning the parsing consists of translating a token into an ast-node with the value.
type ExprKind =
// ...
| { type: "ident", value: string }
| { type: "int", value: number }
| { type: "string", value: string }
// ...
;
class Parser {
// ...
public parseOperand(): Expr {
// ...
if (this.test("ident")) {
const value = this.current().identValue;
this.step();
return this.expr({ type: "ident", value }, pos);
}
if (this.test("int")) {
const value = this.current().intValue;
this.step();
return this.expr({ type: "int", value }, pos);
}
if (this.test("string")) {
const value = this.current().stringValue;
this.step();
return this.expr({ type: "string", value }, pos);
}
// ...
}
// ...
}
3.3.2 Group expressions
A group expression is an expression enclosed in parenthesis, eg (1 + 2)
. Because the expression is enclosed, meaning starts with a (
-token and ends with a )
-token, we will treat is like an operand.
type ExprKind =
// ...
| { type: "group", expr: Expr }
// ...
;
If we find a (
-token in .parseOperand()
, we know that we should parse a group expression. We do this by ignoring the (
-token, parsing an expression using .parseExpr()
and checking that we find a )
-token afterwards.
class Parser {
// ...
public parseOperand(): Expr {
// ...
if (this.test("(")) {
this.step();
const expr = this.parseExpr();
if (!this.test(")")) {
this.report("expected ')'");
return this.expr({ type: "error" }, pos);
}
this.step();
return this.expr({ type: "group", expr }, pos);
}
// ...
}
// ...
}
If we do not find the closing )
-token, we report an error and return an error expression.
3.3.3 Block, if and loop operands
We want to be able to use blocks, if and loop constructs as expressions.
Example:
let temperature_feeling = if > temperature 20 { "hot" } else { "cold" };
Each construct will have their own .parse...()
-method, so we'll just look for the first {
-, if
-, or loop
-token and call the relevant method.
class Parser {
// ...
public parseOperand(): Expr {
// ...
if (this.test("{"))
return this.parseBlock();
if (this.test("if"))
return this.parseIf();
if (this.test("loop"))
return this.parseLoop();
// ...
}
// ...
}
3.4 Postfix operators
Postfix operations are expressions were the operators come after the subject expression. This includes field expressions (eg. subject.field
), index expressions (eg. subject[index]
) and call expressions (eg. subject(...args)
).
A notable detail, is that postfix operations are chainable, eg. subject[index].field
is valid, likewise with subject.method(arg)
and matrix[y][x]
.
We'll make a method .parsePostfix()
to parse postfix operators.
class Parser {
// ...
public parsePostfix(): Expr {
let subject = this.parseOperand();
while (true) {
const pos = this.pos();
// ...
break;
}
return subject;
}
// ...
}
We start by parsing an operand. Then we enter a loop, which runs until we no longer find any relevant operator tokens. When we parse a postfix expression, the subject
will be replaced with the new parsed expression.
Notice we don't define pos
at the start, but after we've parsed the subject. That's because we want pos
to the reflect the start of the postfix operator, not the start of the subject.
3.4.1 Field expressions
A field expression is for accessing fields on an object, and consists of a .
-token and an identifier, eg. .field
.
type ExprKind =
// ...
| { type: "field", subject: Expr, value: string }
// ...
;
class Parser {
// ...
public parsePostfix(): Expr {
// ...
while (true) {
// ...
if (this.test(".")) {
this.step();
if (!this.test("ident")) {
this.report("expected ident");
return this.expr({ type: "error" }, pos);
}
const value = this.current().identValue;
this.step();
subject = this.expr({ type: "field", subject, value }, pos);
continue;
}
// ...
}
// ...
}
// ...
}
If we find a .
-token, we step over it, and make sure that we've hit an identifier. We save the identifier value and step over the identifier. Then we replace subject
with a new field expression containing the previous subject
value. Then we continue to look for the next postfix operator.
3.4.2 Index expressions
An index operation consists of the subject and an index. The index is an expression, and it is contained in [
- and ]
-tokens, eg. subject[value]
.
type ExprKind =
// ...
| { type: "index", subject: Expr, value: Expr }
// ...
;
class Parser {
// ...
public parsePostfix(): Expr {
// ...
while (true) {
// ...
if (this.test("[")) {
this.step();
const value = this.parseExpr();
if (!this.test("]") {
this.report("expected ']'");
return this.expr({ type: "error" }, pos);
}
this.step();
subject = this.expr({ type: "index", subject, value }, pos);
continue;
}
// ...
}
// ...
}
// ...
}
If we find a [
-token, we parse the index part exactly the same way, we parse a group expression.
3.4.3 Call expressions
A call expression is like an index expression, except that it uses (
and )
instead of [
and ]
and that there can be 0 or more expressions (arguments or args) inside the (
and )
. The arguments are seperated by ,
.
type ExprKind =
// ...
| { type: "call", subject: Expr, args: Expr[] }
// ...
;
class Parser {
// ...
public parsePostfix(): Expr {
// ...
while (true) {
// ...
if (this.test("(")) {
this.step();
let args: Expr[] = [];
if (!this.test(")") {
args.push(this.parseExpr());
while (this.test(",")) {
this.step();
if (this.test(")"))
break;
args.push(this.parseExpr());
}
}
const value = this.parseExpr();
if (!this.test(")") {
this.report("expected ')'");
return this.expr({ type: "error" }, pos);
}
this.step();
subject = this.expr({ type: "call", subject, args }, pos);
continue;
}
// ...
}
// ...
}
// ...
}
Similarly to index expressions, if we find a (
-token, we step over it, parse the arguments, check for a )
and replace subject
with a call expression containing the previous subject
.
When parsing the arguments, we start by testing if we've reached a )
to check if there are any arguments. If not, we parse the first argument.
The consecutive arguments are all preceded by a ,
-token. There we test for ,
, to check if we should keep parsing arguments. After checking for a seperating ,
, we check if we've reached a )
and break if so. This is to allow for trailing comma.
func(
a,
b, // trailing comma
)
3.5 Prefix expressions
Contrasting postfix expressions, prefix expression are operations where the operator comes first, then the operands are listed. In some languages, operations such as negation (eg. -value
) and not-operations (eg. !value
) are prefix operations. In the language we're making, all binary and unary arithmetic operations are prefix. This includes both expressions with a single operand, such as not (eg. not value
), but also expressions with 2 operands, such as addition (eg. + a b
) and equation (eg. == a b
).
This is because infix operators (eg. a + b
) makes parsing more complicated, as it requires reasoning about operator precedence, eg. why 2 + 3 * 4 != (2 + 3) * 4
.
Operations with 1 operand are called unary expression. Operations with 2 are called binary expressions.
type ExprKind =
// ...
| { type: "unary", unaryType: UnaryType, subject: Expr }
| { type: "binary", binaryType: BinaryType, left: Expr, right: Expr }
// ...
;
type UnaryType = "not" /*...*/;
type BinaryType = "+" | "*" | "==" /*...*/;
class Parser {
// ...
public parsePrefix(): Expr {
const pos = this.pos();
// ...
return this.parsePostfix();
}
// ...
}
We again get the position immediately, because the operation, eg. + a b
, starts at the first +
-token.
If we don't find any operators, we proceed to try to parse a postfix expression.
3.5.1 Unary expressions
class Parser {
// ...
public parsePrefix(): Expr {
// ...
if (this.test("not")) {
this.step();
const subject = this.parsePrefix();
return this.expr({ type: "unary", unaryType: "not", subject }, pos);
}
// ...
}
// ...
}
If we find a not
-token, we ignore it, parse a prefix expression recursively, and return a unary expression with the subject
and unary type.
3.5.2 Binary expressions
class Parser {
// ...
public parsePrefix(): Expr {
// ...
if (this.test("+")) {
this.step();
const left = this.parsePrefix();
const right = this.parsePrefix();
return this.expr({ type: "binary", binaryType: "+", left, right }, pos);
}
// ...
}
// ...
}
Just as with unary, if we find a +
-token, we ignore it and parse prefix expression recursively. Then we parse the second operand, by parsing another prefix expressions. And then we return a binary expression with the left
and right
operands and the binary type.
3.6 Expressions
Lastly for expressions, we'll make a method .parseExpr()
for parsing an expression.
class Parser {
// ...
public parseExpr(): Expr {
return this.parsePrefix();
}
// ...
}
The method just proceeds to try and parse a prefix expression.
3.7 If expressions
An if-expression is an if
-token, followed by an condition in the form of an expressions, followed by a block-expression, optionally followed by an else
-token and another block.
type ExprKind =
// ...
| { type: "if", cond: Expr, truthy: Expr, falsy?: Expr }
// ...
;
class Parser {
// ...
public parseIf(): Expr {
const pos = this.pos();
this.step();
const cond = this.parseExpr();
if (!this.test("{")) {
this.report("expected block");
return this.expr({ type: "error" }, pos);
}
const truthy = this.parseBlock();
if (!this.test("else")) {
return this.expr({ type: "if", cond, truthy }, pos);
}
this.step();
if (this.test("if")) {
const falsy = this.parseIf();
return this.expr({ type: "if", cond, truthy, falsy }, pos);
}
if (!this.test("{")) {
this.report("expected block");
return this.expr({ type: "error" }, pos);
}
const falsy = this.parseBlock();
return this.expr({ type: "if", cond, truthy, falsy }, pos);
}
// ...
}
When parsing an if-expression, we assume we already have reached an if
-token.
We skip the if
-token. Then we parse the condition expression cond
. Then we check for a {
-token and parse block. Then we check for an else
-token. If not present, we return an if-expression with no falsy
-option. Else we skip the else
-token. If we find a if
-token, it means we're parsing an else-if construct, in which case we parse an if expression recursively. Else check for and parse the falsy
-block. And then return the if-expression with the falsy
-option.
3.8 Loop expressions
A loop expression is a loop
-token followed by a block expression.
type ExprKind =
// ...
| { type: "loop", body: Expr }
// ...
;
class Parser {
// ...
public parseLoop(): Expr {
const pos = this.pos();
this.step();
if (!this.test("{")) {
this.report("expected '}'");
return this.expr({ type: "error" }, pos);
}
const body = this.parseExpr();
return this.expr({ type: "loop", body }, pos);
}
// ...
}
We again assume, we've already hit a loop
-token, which we step over. Then we check for and parse a block expression constituting the loop body
. We then return the loop expression.
3.9 Break statements
A break statement consists of a break
-token and an optional expression.
The language will allow us to use loop as an expression. The break statement will then deliver the resulting value, eg.
let value = loop {
let value = get_value();
if acceptable(value) {
break value;
}
};
type StmtKind =
// ...
| { type: "break", expr?: Expr }
// ...
;
class Parser {
// ...
public parseBreak(): Stmt {
const pos = this.pos();
this.step();
if (!this.test(";")) {
return this.stmt({ type: "break" }, pos);
}
const expr = this.parseExpr();
return this.stmt({ type: "break", expr }, pos);
}
// ...
}
We assume we've already hit a break
-token and step over it. Then we check if we've hit a ;
-token. If so, there's no expression, so we return a break statement with no expression. If there's no ;
-token, we parse an expression and return a break statement with it.
3.9 Return statements
The return statement is for functions what break is for loops.
type StmtKind =
// ...
| { type: "return", expr?: Expr }
// ...
;
class Parser {
// ...
public parseReturn(): Stmt {
const pos = this.pos();
this.step();
if (!this.test(";")) {
return this.stmt({ type: "return" }, pos);
}
const expr = this.parseExpr();
return this.stmt({ type: "return", expr }, pos);
}
// ...
}
3.10 Function definition statements
A function definition statement or 'fn'-statement for short is a statement that defines a function with it's name, parameters and body.
The function name is an identifier. The body is a block expression. The parameters is a list of identifiers seperated by ,
, enclosed in (
and )
.
An fn statements consists of an fn
-token, an it's name as an identifier token, a parameter list, and the body.
type StmtKind =
// ...
| { type: "fn", ident: string, params: Param[], body: Expr }
// ...
;
type Param = {
ident: string,
pos: Pos,
};
We start by defining a method .parseFn()
to parse function definitions.
class Parser {
// ...
public parseFn(): Stmt {
const pos = this.pos();
this.step();
if (!this.test("ident")) {
this.report("expected ident");
return this.stmt({ type: "error" }, pos);
}
const ident = this.current().identValue;
this.step();
if (!this.test("(")) {
this.report("expected '('");
return this.stmt({ type: "error" }, pos);
}
const params = this.parseFnParams();
if (!params.ok)
return this.stmt({ type: "error" }, pos);
if (!this.test("{")) {
this.report("expected block");
return this.stmt({ type: "error" }, pos);
}
const body = this.parseBlock();
return this.stmt({ type: "fn", ident, params: params.value, body }, pos);
}
// ...
}
We first step over the initial fn
-token. Then we grab the value of an ident
-token. Then we check for a (
and call .parseFnParams()
to parse the parameters, including the encapsulating (
and )
. Then we check for and parse a block. And then we return the statement.
Then we define the .parseFnParams()
method.
class Parser {
// ...
public parseFnParams(): Param[] {
this.step();
if (this.test(")")) {
this.step();
return [];
}
let params: Param[] = [];
const paramResult = this.parseParam();
if (!paramResult.ok)
return [];
params.push(paramResult.value);
while (this.test(",")) {
this.step();
if (this.test(")"))
break;
const paramResult = this.parseParam();
if (!paramResult.ok)
return [];
params.push(paramResult.value);
}
if (!this.test(")")) {
this.report("expected ')'");
return params;
}
this.step();
return params;
}
// ...
}
We represent the parameter list as an array of params. We start by stepping over the (
-token. If we immediately find a )
-token, we step and return an empty array. Else we start collecting parameters. The parsing is similar to function call arguments, wherein we parse the first, then keep parsing until we no longer find a ,
-token or find a )
-token right after a ,
. When done, we check we've reached a )
, step and return the parameters. If .parseParam()
fails, we return an empty array.
We then need to define the .parseParam()
method.
class Parser {
// ...
public parseParam(): { ok: true, value: Param } | { ok: false } {
const pos = this.pos();
if (this.test("ident")) {
const ident = self.current().value;
this.step();
return { ok: true, value: { ident, pos } };
}
this.report("expected param");
return { ok: false };
}
// ...
}
We look for an identifier, and return a parameter with its value. If we don't find an identifier, we return a failed result.
3.10 Let statements
A let statement declares a variable. A let statement consists of a let
-token, a parameter, a =
-token, and an expression. The expression is the initial value of the variable.
type StmtKind =
// ...
| { type: "let", param: Param, value: Expr }
// ...
;
class Parser {
// ...
public parseLet(): Stmt {
const pos = this.pos();
this.step();
const paramResult = this.parseParam();
if (!paramResult.ok)
return this.stmt({ type: "error" }, pos);
const param = paramResult.value;
if (!this.test("=")) {
this.report("expected '='");
return this.stmt({ type: "error" }, pos);
}
this.step();
const value = this.parseExpr();
return this.stmt({ type: "let", param, value }, pos);
}
// ...
}
We step over the first let
-token. Then we parse a parameter using the .parseParam()
method. If it fails, we return an error statement. Then we check for and step over a =
-token. We then parse an expression. And lastly return a let statement with the ident
and value
.
3.14 Assignment and expression statements
An assignment statement is an assignable expression (we'll just parse an expression), then a =
token and another expression.
Additionally, if an expression is used as a statement, it becomes an expression statement. This is important in this step.
type StmtKind =
// ...
| { type: "assign", subject: Expr, value: Expr }
| { type: "expr", expr: Expr }
// ...
;
class Parser {
// ...
public parseAssign(): Stmt {
const pos = this.pos();
const subject = this.parseExpr();
if (!this.test("=")) {
return this.stmt({ type: "expr", expr: subject }, pos);
}
this.step();
const value = this.parseExpr();
return this.stmt({ type: "assign", subject, value }, pos);
}
// ...
}
We start by parsing an expression. If we do not reach a =
afterwards, we return an expression statement. Else, we step, parse another expression and return an assignment statement.
3.13 Block expressions
Block expressions are statements and an optional expressions surrounded by {
and }
. Statements are terminated by ;
, if they don't end in }
. If an expression is given as the last item without a terminating ;
, it is the blocks resulting value.
Example:
let a = { 123 }; // a == 123
let a = { let b = 123; b }; // a == 123
let c = { if == a b { 123 } }; // c = 123
let c = { if == a b { 123 } 321 }; // c = 321
type ExprKind =
// ...
| { type: "block", stmts: Stmt[], expr?: Expr }
// ...
;
class Parser {
// ...
public parseBlock(): Expr {
const pos = this.pos();
this.step();
let stmts: Stmt[] = [];
while (!this.done()) {
// ...
}
this.report("expected '}'");
return this.expr({ type: "error" }, pos);
}
// ...
}
We step over the {
and begin looping. We expect to return inside the loop, so we report an error, if the loop runs through.
class Parser {
// ...
public parseBlock(): Expr {
// ...
while (!this.done()) {
if (this.test("}")) {
return this.expr({ type: "block", stmts }, pos);
// ...
}
}
// ...
}
// ...
}
If we reach a }
, return a block with the statements.
class Parser {
// ...
public parseBlock(): Expr {
// ...
while (!this.done()) {
if (this.test("}")) {
// ...
} else if (this.test("fn")) {
stmts.push(this.parseFn());
// ...
}
}
// ...
}
// ...
}
If we reach a fn
-token, we parse a fn statement and continue parsing statements.
class Parser {
// ...
public parseBlock(): Expr {
// ...
while (!this.done()) {
if (this.test("}")) {
// ...
} else if (this.test("let") || this.test("return") || this.test("break")) {
stmts.push(this.parseSingleLineBlockStmt());
this.eatSemicolon();
// ...
}
}
// ...
}
// ...
private parseSingleLineBlockStmt(): Stmt {
if (this.test("let"))
return this.parseLet();
if (this.test("return"))
return this.parseReturn();
if (this.test("break"))
return this.parseBreak();
this.report("expected stmt");
return this.stmt({ type: "error" }, pos);
}
// ...
private eatSemicolon() {
if (!this.test(";")) {
this.report("expected ';'");
return;
}
this.step();
}
// ...
}
If we reach a token designating the start of a single line statement, such as let
in a let statement, return
, break
, parse a single line block statement, then check for a ;
-token. Then continue parsing statements.
class Parser {
// ...
public parseBlock(): Expr {
// ...
while (!this.done()) {
if (this.test("}")) {
// ...
} else if (this.test("{") || this.test("if") || this.test("loop")) {
let expr = this.parseMultiLineBlockExpr();
if (this.test("}")) {
this.step();
return this.expr({ type: "block", stmts, expr }, pos);
}
stmts.push(this.stmt({ type: "expr", expr }, expr.pos));
// ...
}
}
// ...
}
// ...
private parseMultiLineBlockExpr(): Expr {
if (this.test("{"))
return this.parseBlock();
if (this.test("if"))
return this.parseIf();
if (this.test("loop"))
return this.parseLoop();
this.report("expected expr");
return this.expr({ type: "error" }, pos);
}
// ...
}
If we reach a token designating an expression or statement ending with a }
, such as if
, loop
and {
as in a block expression, parse a multi line expression. If we've hit the end of the block, then return a block expression with the parsed multi line expression as the resuling value. Otherwise, push the expression as an expression statement.
class Parser {
// ...
public parseBlock(): Expr {
// ...
while (!this.done()) {
if (this.test("}")) {
// ...
} else {
const expr = this.parseExpr();
if (this.test("=")) {
this.step();
const value = this.parseExpr();
this.eatSemicolon();
stmts.push(this.stmt({ type: "assign", subject: expr, value }, pos));
} else if (this.test(";")) {
stmts.push(this.stmt({ type: "expr", expr }, expr.pos));
} else if (this.test("}")) {
return this.expr({ type: "block", stmts, expr }, pos);
} else {
this.report("expected ';' or '}'");
return this.expr({ type: "error" }, pos);
}
}
}
// ...
}
// ...
}
If we don't recognize the token we've reached, we assume it's an expression. If we reach =
after parsing the initial expression, we try to parse an assignment statement. Since we cannot use the .parseAssign()
method here, we do the same here as in that method, then check that we hit a ;
, and then push the assignment statement instead of returning. If instead we hit a ;
, we push the expression as an expression statements. Else, if we hit a }
, we've reached the end of the block, and we return a block expression with the parsed expression as the resulting value. Otherwise, we report an error.
3.14 Statements
Lastly, we'll define a method .parseStmts()
for parsing top level statements.
class Parser {
// ...
public parseStmts(): Stmt[] {
let stmts: Stmt[] = [];
while (!this.done()) {
// ...
}
return stmts;
}
// ...
}
We want to parse every statement in the file, so we loop until we've reach the end.
class Parser {
// ...
public parseStmts(): Stmt[] {
let stmts: Stmt[] = [];
while (!this.done()) {
if (this.test("fn")) {
stmts.push(this.parseFn());
// ...
}
}
return stmts;
}
// ...
}
We first test, if we've reached a multi line statement ending in a }
, such as a fn statement.
class Parser {
// ...
public parseStmts(): Stmt[] {
let stmts: Stmt[] = [];
while (!this.done()) {
if (this.test("fn")) {
// ...
} else if (this.test("let") || this.test("return") || this.test("break")) {
stmts.push(this.parseSingleLineBlockStmt());
this.eatSemicolon();
// ...
}
}
return stmts;
}
// ...
}
Then we test, if we've reached a single line statement, meaning it should end with a ;
, such as let, return and break.
class Parser {
// ...
public parseStmts(): Stmt[] {
let stmts: Stmt[] = [];
while (!this.done()) {
if (this.test("fn")) {
// ...
} else if (this.test("{") || this.test("if") || this.test("loop")) {
let expr = this.parseMultiLineBlockExpr();
stmts.push(this.stmt({ type: "expr", expr }, expr.pos));
// ...
}
}
return stmts;
}
// ...
}
Then we test, if we've reached a multi line expression ending in }
, such as if, loop and a block expression.
class Parser {
// ...
public parseStmts(): Stmt[] {
let stmts: Stmt[] = [];
while (!this.done()) {
if (this.test("fn")) {
// ...
} else {
stmts.push(this.parseAssign());
}
}
return stmts;
}
// ...
}
If none of the above, we parse an assignment statement, which will parse an assignment statement or an expression statement.
Exercises
- Implement boolean literals:
true
andfalse
and null literal:null
. - Implement the binary operators:
-
,*
,/
,!=
,<
,>
,<=
,>=
,or
andand
. - * Implement hex integer literals.
- * Implement array literal syntax, eg.
[a, b c]
. - * Implement struct literal syntax, eg.
struct { field: expr, field: expr, ... }
. - ** Implement infix notation, eg.
a + b
, as compared to+ a b
.