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|
## This is the LuxC's parser.
## It takes the source code of a Lux file in raw text form and
## extracts the syntactic structure of the code from it.
## It only produces Lux Code nodes, and thus removes any white-space
## and comments while processing its inputs.
## Another important aspect of the parser is that it keeps track of
## its position within the input data.
## That is, the parser takes into account the line and column
## information in the input text (it doesn't really touch the
## file-name aspect of the cursor, leaving it intact in whatever
## base-line cursor it is given).
## This particular piece of functionality is not located in one
## function, but it is instead scattered throughout several parsers,
## since the logic for how to update the cursor varies, depending on
## what is being parsed, and the rules involved.
## You will notice that several parsers have a "where" parameter, that
## tells them the cursor position prior to the parser being run.
## They are supposed to produce some parsed output, alongside an
## updated cursor pointing to the end position, after the parser was run.
## Lux Code nodes/tokens are annotated with cursor meta-data
## (file-name, line, column) to keep track of their provenance and
## location, which is helpful for documentation and debugging.
(;module:
lux
(lux (control monad
["p" parser "p/" Monad<Parser>])
(data [bool]
[text]
["e" error]
[number]
[product]
[maybe]
(text ["l" lexer]
format)
(coll [sequence #+ Sequence]))))
(def: white-space Text "\t\v \r\f")
(def: new-line Text "\n")
## This is the parser for white-space.
## Whenever a new-line is encountered, the column gets reset to 0, and
## the line gets incremented.
## It operates recursively in order to produce the longest continuous
## chunk of white-space.
(def: (space^ where)
(-> Cursor (l;Lexer [Cursor Text]))
(p;either (do p;Monad<Parser>
[content (l;many (l;one-of white-space))]
(wrap [(update@ #;column (n.+ (text;size content)) where)
content]))
## New-lines must be handled as a separate case to ensure line
## information is handled properly.
(do p;Monad<Parser>
[content (l;many (l;one-of new-line))]
(wrap [(|> where
(update@ #;line (n.+ (text;size content)))
(set@ #;column +0))
content]))
))
## Single-line comments can start anywhere, but only go up to the
## next new-line.
(def: (single-line-comment^ where)
(-> Cursor (l;Lexer [Cursor Text]))
(do p;Monad<Parser>
[_ (l;this "##")
comment (l;some (l;none-of new-line))
_ (l;this new-line)]
(wrap [(|> where
(update@ #;line n.inc)
(set@ #;column +0))
comment])))
## This is just a helper parser to find text which doesn't run into
## any special character sequences for multi-line comments.
(def: comment-bound^
(l;Lexer Unit)
($_ p;either
(l;this new-line)
(l;this ")#")
(l;this "#(")))
## Multi-line comments are bounded by #( these delimiters, #(and, they may
## also be nested)# )#.
## Multi-line comment syntax must be balanced.
## That is, any nested comment must have matched delimiters.
## Unbalanced comments ought to be rejected as invalid code.
(def: (multi-line-comment^ where)
(-> Cursor (l;Lexer [Cursor Text]))
(do p;Monad<Parser>
[_ (l;this "#(")]
(loop [comment ""
where (update@ #;column (n.+ +2) where)]
($_ p;either
## These are normal chunks of commented text.
(do @
[chunk (l;many (l;not comment-bound^))]
(recur (format comment chunk)
(|> where
(update@ #;column (n.+ (text;size chunk))))))
## This is a special rule to handle new-lines within
## comments properly.
(do @
[_ (l;this new-line)]
(recur (format comment new-line)
(|> where
(update@ #;line n.inc)
(set@ #;column +0))))
## This is the rule for handling nested sub-comments.
## Ultimately, the whole comment is just treated as text
## (the comment must respect the syntax structure, but the
## output produced is just a block of text).
## That is why the sub-comment is covered in delimiters
## and then appended to the rest of the comment text.
(do @
[[sub-where sub-comment] (multi-line-comment^ where)]
(recur (format comment "#(" sub-comment ")#")
sub-where))
## Finally, this is the rule for closing the comment.
(do @
[_ (l;this ")#")]
(wrap [(update@ #;column (n.+ +2) where)
comment]))
))))
## This is the only parser that should be used directly by other
## parsers, since all comments must be treated as either being
## single-line or multi-line.
## That is, there is no syntactic rule prohibiting one type of comment
## from being used in any situation (alternatively, forcing one type
## of comment to be the only usable one).
(def: (comment^ where)
(-> Cursor (l;Lexer [Cursor Text]))
(p;either (single-line-comment^ where)
(multi-line-comment^ where)))
## To simplify parsing, I remove any left-padding that an Code token
## may have prior to parsing the token itself.
## Left-padding is assumed to be either white-space or a comment.
## The cursor gets updated, but the padding gets ignored.
(def: (left-padding^ where)
(-> Cursor (l;Lexer Cursor))
($_ p;either
(do p;Monad<Parser>
[[where comment] (comment^ where)]
(left-padding^ where))
(do p;Monad<Parser>
[[where white-space] (space^ where)]
(left-padding^ where))
(:: p;Monad<Parser> wrap where)))
## Escaped character sequences follow the usual syntax of
## back-slash followed by a letter (e.g. \n).
## Unicode escapes are possible, with hexadecimal sequences between 1
## and 4 characters long (e.g. \u12aB).
## Escaped characters may show up in Char and Text literals.
(def: escaped-char^
(l;Lexer [Nat Text])
(p;after (l;this "\\")
(do p;Monad<Parser>
[code l;any]
(case code
## Handle special cases.
"t" (wrap [+2 "\t"])
"v" (wrap [+2 "\v"])
"b" (wrap [+2 "\b"])
"n" (wrap [+2 "\n"])
"r" (wrap [+2 "\r"])
"f" (wrap [+2 "\f"])
"\"" (wrap [+2 "\""])
"\\" (wrap [+2 "\\"])
## Handle unicode escapes.
"u"
(do p;Monad<Parser>
[code (l;between +1 +4 l;hexadecimal)]
(wrap (case (|> code (format "+") (:: number;Hex@Codec<Text,Nat> decode))
(#;Right value)
[(n.+ +2 (text;size code)) (text;from-code value)]
_
(undefined))))
_
(p;fail (format "Invalid escaping syntax: " (%t code)))))))
## These are very simple parsers that just cut chunks of text in
## specific shapes and then use decoders already present in the
## standard library to actually produce the values from the literals.
(def: rich-digit
(l;Lexer Text)
(p;either l;decimal
(p;after (l;this "_") (p/wrap ""))))
(def: rich-digits^
(l;Lexer Text)
(l;seq l;decimal
(l;some rich-digit)))
(def: (marker^ token)
(-> Text (l;Lexer Text))
(p;after (l;this token) (p/wrap token)))
(do-template [<name> <tag> <lexer> <codec>]
[(def: #export (<name> where)
(-> Cursor (l;Lexer [Cursor Code]))
(do p;Monad<Parser>
[chunk <lexer>]
(case (:: <codec> decode chunk)
(#;Left error)
(p;fail error)
(#;Right value)
(wrap [(update@ #;column (n.+ (text;size chunk)) where)
[where (<tag> value)]]))))]
[bool #;Bool
(p;either (marker^ "true") (marker^ "false"))
bool;Codec<Text,Bool>]
[int #;Int
(l;seq (p;default "" (l;one-of "-"))
rich-digits^)
number;Codec<Text,Int>]
[deg #;Deg
(l;seq (l;one-of ".")
rich-digits^)
number;Codec<Text,Deg>]
)
(def: (nat-char where)
(-> Cursor (l;Lexer [Cursor Code]))
(do p;Monad<Parser>
[_ (l;this "#\"")
[where' char] (: (l;Lexer [Cursor Text])
($_ p;either
## Normal text characters.
(do @
[normal (l;none-of "\\\"\n")]
(wrap [(|> where
(update@ #;column n.inc))
normal]))
## Must handle escaped
## chars separately.
(do @
[[chars-consumed char] escaped-char^]
(wrap [(|> where
(update@ #;column (n.+ chars-consumed)))
char]))))
_ (l;this "\"")
#let [char (maybe;assume (text;nth +0 char))]]
(wrap [(|> where'
(update@ #;column n.inc))
[where (#;Nat char)]])))
(def: (normal-nat where)
(-> Cursor (l;Lexer [Cursor Code]))
(do p;Monad<Parser>
[chunk (l;seq (l;one-of "+")
rich-digits^)]
(case (:: number;Codec<Text,Nat> decode chunk)
(#;Left error)
(p;fail error)
(#;Right value)
(wrap [(update@ #;column (n.+ (text;size chunk)) where)
[where (#;Nat value)]]))))
(def: #export (nat where)
(-> Cursor (l;Lexer [Cursor Code]))
(p;either (normal-nat where)
(nat-char where)))
(def: (normal-frac where)
(-> Cursor (l;Lexer [Cursor Code]))
(do p;Monad<Parser>
[chunk ($_ l;seq
(p;default "" (l;one-of "-"))
rich-digits^
(l;one-of ".")
rich-digits^
(p;default ""
($_ l;seq
(l;one-of "eE")
(p;default "" (l;one-of "+-"))
rich-digits^)))]
(case (:: number;Codec<Text,Frac> decode chunk)
(#;Left error)
(p;fail error)
(#;Right value)
(wrap [(update@ #;column (n.+ (text;size chunk)) where)
[where (#;Frac value)]]))))
(def: frac-ratio-fragment
(l;Lexer Frac)
(<| (p;codec number;Codec<Text,Frac>)
(:: p;Monad<Parser> map (function [digits]
(format digits ".0")))
rich-digits^))
(def: (ratio-frac where)
(-> Cursor (l;Lexer [Cursor Code]))
(do p;Monad<Parser>
[chunk ($_ l;seq
(p;default "" (l;one-of "-"))
rich-digits^
(l;one-of "/")
rich-digits^)
value (l;local chunk
(do @
[signed? (l;this? "-")
numerator frac-ratio-fragment
_ (l;this? "/")
denominator frac-ratio-fragment
_ (p;assert "Denominator cannot be 0."
(not (f.= 0.0 denominator)))]
(wrap (|> numerator
(f.* (if signed? -1.0 1.0))
(f./ denominator)))))]
(wrap [(update@ #;column (n.+ (text;size chunk)) where)
[where (#;Frac value)]])))
(def: #export (frac where)
(-> Cursor (l;Lexer [Cursor Code]))
(p;either (normal-frac where)
(ratio-frac where)))
## This parser looks so complex because text in Lux can be multi-line
## and there are rules regarding how this is handled.
(def: #export (text where)
(-> Cursor (l;Lexer [Cursor Code]))
(do p;Monad<Parser>
[## Lux text "is delimited by double-quotes", as usual in most
## programming languages.
_ (l;this "\"")
## I must know what column the text body starts at (which is
## always 1 column after the left-delimiting quote).
## This is important because, when procesing subsequent lines,
## they must all start at the same column, being left-padded with
## as many spaces as necessary to be column-aligned.
## This helps ensure that the formatting on the text in the
## source-code matches the formatting of the Text value.
#let [offset-column (n.inc (get@ #;column where))]
[where' text-read] (: (l;Lexer [Cursor Text])
## I must keep track of how much of the
## text body has been read, how far the
## cursor has progressed, and whether I'm
## processing a subsequent line, or just
## processing normal text body.
(loop [text-read ""
where (|> where
(update@ #;column n.inc))
must-have-offset? false]
(p;either (if must-have-offset?
## If I'm at the start of a
## new line, I must ensure the
## space-offset is at least
## as great as the column of
## the text's body's column,
## to ensure they are aligned.
(do @
[offset (l;many (l;one-of " "))
#let [offset-size (text;size offset)]]
(if (n.>= offset-column offset-size)
## Any extra offset
## becomes part of the
## text's body.
(recur (|> offset
(text;split offset-column)
(maybe;default (undefined))
product;right
(format text-read))
(|> where
(update@ #;column (n.+ offset-size)))
false)
(p;fail (format "Each line of a multi-line text must have an appropriate offset!\n"
"Expected: " (%i (nat-to-int offset-column)) " columns.\n"
" Actual: " (%i (nat-to-int offset-size)) " columns.\n"))))
($_ p;either
## Normal text characters.
(do @
[normal (l;many (l;none-of "\\\"\n"))]
(recur (format text-read normal)
(|> where
(update@ #;column (n.+ (text;size normal))))
false))
## Must handle escaped
## chars separately.
(do @
[[chars-consumed char] escaped-char^]
(recur (format text-read char)
(|> where
(update@ #;column (n.+ chars-consumed)))
false))
## The text ends when it
## reaches the right-delimiter.
(do @
[_ (l;this "\"")]
(wrap [(update@ #;column n.inc where)
text-read]))))
## If a new-line is
## encountered, it gets
## appended to the value and
## the loop is alerted that the
## next line must have an offset.
(do @
[_ (l;this new-line)]
(recur (format text-read new-line)
(|> where
(update@ #;line n.inc)
(set@ #;column +0))
true)))))]
(wrap [where'
[where (#;Text text-read)]])))
## Form and tuple syntax is mostly the same, differing only in the
## delimiters involved.
## They may have an arbitrary number of arbitrary Code nodes as elements.
(do-template [<name> <tag> <open> <close>]
[(def: (<name> where ast)
(-> Cursor
(-> Cursor (l;Lexer [Cursor Code]))
(l;Lexer [Cursor Code]))
(do p;Monad<Parser>
[_ (l;this <open>)
[where' elems] (loop [elems (: (Sequence Code)
sequence;empty)
where where]
(p;either (do @
[## Must update the cursor as I
## go along, to keep things accurate.
[where' elem] (ast where)]
(recur (sequence;add elem elems)
where'))
(do @
[## Must take into account any
## padding present before the
## end-delimiter.
where' (left-padding^ where)
_ (l;this <close>)]
(wrap [(update@ #;column n.inc where')
(sequence;to-list elems)]))))]
(wrap [where'
[where (<tag> elems)]])))]
[form #;Form "(" ")"]
[tuple #;Tuple "[" "]"]
)
## Records are almost (syntactically) the same as forms and tuples,
## with the exception that their elements must come in pairs (as in
## key-value pairs).
## Semantically, though, records and tuples are just 2 different
## representations for the same thing (a tuple).
## In normal Lux syntax, the key position in the pair will be a tag
## Code node, however, record Code nodes allow any Code node to occupy
## this position, since it may be useful when processing Code syntax in
## macros.
(def: (record where ast)
(-> Cursor
(-> Cursor (l;Lexer [Cursor Code]))
(l;Lexer [Cursor Code]))
(do p;Monad<Parser>
[_ (l;this "{")
[where' elems] (loop [elems (: (Sequence [Code Code])
sequence;empty)
where where]
(p;either (do @
[[where' key] (ast where)
[where' val] (ast where')]
(recur (sequence;add [key val] elems)
where'))
(do @
[where' (left-padding^ where)
_ (l;this "}")]
(wrap [(update@ #;column n.inc where')
(sequence;to-list elems)]))))]
(wrap [where'
[where (#;Record elems)]])))
## The parts of an identifier are separated by a single mark.
## E.g. module;name.
## Only one such mark may be used in an identifier, since there
## can only be 2 parts to an identifier (the module [before the
## mark], and the name [after the mark]).
## There are also some extra rules regarding identifier syntax,
## encoded on the parser.
(def: identifier-separator Text ";")
## A Lux identifier is a pair of chunks of text, where the first-part
## refers to the module that gives context to the identifier, and the
## second part corresponds to the name of the identifier itself.
## The module part may be absent (by being the empty text ""), but the
## name part must always be present.
## The rules for which characters you may use are specified in terms
## of which characters you must avoid (to keep things as open-ended as
## possible).
## In particular, no white-space can be used, and neither can other
## characters which are already used by Lux as delimiters for other
## Code nodes (thereby reducing ambiguity while parsing).
## Additionally, the first character in an identifier's part cannot be
## a digit, to avoid confusion with regards to numbers.
(def: ident-part^
(l;Lexer Text)
(do p;Monad<Parser>
[#let [digits "0123456789"
delimiters (format "()[]{}#\"" identifier-separator)
space (format white-space new-line)
head-lexer (l;none-of (format digits delimiters space))
tail-lexer (l;some (l;none-of (format delimiters space)))]
head head-lexer
tail tail-lexer]
(wrap (format head tail))))
(def: ident^
(l;Lexer [Ident Nat])
($_ p;either
## When an identifier starts with 2 marks, it's module is
## taken to be the current-module being compiled at the moment.
## This can be useful when mentioning identifiers and tags
## inside quoted/templated code in macros.
(do p;Monad<Parser>
[#let [current-module-mark (format identifier-separator identifier-separator)]
_ (l;this current-module-mark)
def-name ident-part^]
(p;fail (format "Cannot handle " current-module-mark " syntax for identifiers.")))
## If the identifier is prefixed by the mark, but no module
## part, the module is assumed to be "lux" (otherwise known as
## the 'prelude').
## This makes it easy to refer to definitions in that module,
## since it is the most fundamental module in the entire
## standard library.
(do p;Monad<Parser>
[_ (l;this identifier-separator)
def-name ident-part^]
(wrap [["lux" def-name]
(n.inc (text;size def-name))]))
## Not all identifiers must be specified with a module part.
## If that part is not provided, the identifier will be created
## with the empty "" text as the module.
## During program analysis, such identifiers tend to be treated
## as if their context is the current-module, but this only
## applies to identifiers for tags and module definitions.
## Function arguments and local-variables may not be referred-to
## using identifiers with module parts, so being able to specify
## identifiers with empty modules helps with those use-cases.
(do p;Monad<Parser>
[first-part ident-part^]
(p;either (do @
[_ (l;this identifier-separator)
second-part ident-part^]
(wrap [[first-part second-part]
($_ n.+
(text;size first-part)
+1
(text;size second-part))]))
(wrap [["" first-part]
(text;size first-part)])))))
## The only (syntactic) difference between a symbol and a tag (both
## being identifiers), is that tags must be prefixed with a hash-sign
## (i.e. #).
## Semantically, though, they are very different, with symbols being
## used to refer to module definitions and local variables, while tags
## provide the compiler with information related to data-structure
## construction and de-structuring (during pattern-matching).
(do-template [<name> <tag> <lexer> <extra>]
[(def: #export (<name> where)
(-> Cursor (l;Lexer [Cursor Code]))
(do p;Monad<Parser>
[[value length] <lexer>]
(wrap [(update@ #;column (|>. ($_ n.+ <extra> length)) where)
[where (<tag> value)]])))]
[symbol #;Symbol ident^ +0]
[tag #;Tag (p;after (l;this "#") ident^) +1]
)
(def: (ast where)
(-> Cursor (l;Lexer [Cursor Code]))
(do p;Monad<Parser>
[where (left-padding^ where)]
($_ p;either
(form where ast)
(tuple where ast)
(record where ast)
(bool where)
(nat where)
(frac where)
(int where)
(deg where)
(symbol where)
(tag where)
(text where)
)))
(def: #export (parse [where offset source])
(-> Source (e;Error [Source Code]))
(case (p;run [offset source] (ast where))
(#e;Error error)
(#e;Error error)
(#e;Success [[offset' remaining] [where' output]])
(#e;Success [[where' offset' remaining] output])))
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