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1080 lines
38 KiB
Plaintext
; Copyright (C) 2019-2021 Aleo Systems Inc.
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; This file is part of the Leo library.
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; The Leo library is free software: you can redistribute it and/or modify
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; it under the terms of the GNU General Public License as published by
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; the Free Software Foundation, either version 3 of the License, or
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; (at your option) any later version.
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; The Leo library is distributed in the hope that it will be useful,
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; but WITHOUT ANY WARRANTY; without even the implied warranty of
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; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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; GNU General Public License for more details.
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; You should have received a copy of the GNU General Public License
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; along with the Leo library. If not, see <https://www.gnu.org/licenses/>.
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; Introduction
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; ------------
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; This file contains an ABNF (Augmented Backus-Naur Form) grammar of Leo.
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; Background on ABNF is provided later in this file.
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; This grammar provides an official definition of the syntax of Leo
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; that is both human-readable and machine-readable.
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; It will be part of an upcoming Leo language reference.
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; It may also be used to generate parser tests at some point.
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; We are also using this grammar
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; as part of a mathematical formalization of the Leo language,
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; which we are developing in the ACL2 theorem prover
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; and which we plan to publish at some point.
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; In particular, we have used a formally verified parser of ABNF grammars
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; (at https://github.com/acl2/acl2/tree/master/books/kestrel/abnf;
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; also see the paper at https://www.kestrel.edu/people/coglio/vstte18.pdf)
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; to parse this grammar into a formal representation of the Leo concrete syntax
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; and to validate that the grammar satisfies certain consistency properties.
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; Background on ABNF
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; ------------------
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; ABNF is an Internet standard:
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; see RFC 5234 at https://www.rfc-editor.org/info/rfc5234
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; and RFC 7405 at https://www.rfc-editor.org/info/rfc7405.
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; It is used to specify the syntax of JSON, HTTP, and other standards.
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; ABNF adds conveniences and makes slight modifications
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; to Backus-Naur Form (BNF),
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; without going beyond context-free grammars.
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; Instead of BNF's angle-bracket notation for nonterminals,
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; ABNF uses case-insensitive names consisting of letters, digits, and dashes,
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; e.g. `HTTP-message` and `IPv6address`.
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; ABNF includes an angle-bracket notation for prose descriptions,
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; e.g. `<host, see [RFC3986], Section 3.2.2>`,
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; usable as last resort in the definiens of a nonterminal.
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; While BNF allows arbitrary terminals,
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; ABNF uses only natural numbers as terminals,
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; and denotes them via:
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; (i) binary, decimal, or hexadecimal sequences,
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; e.g. `%b1.11.1010`, `%d1.3.10`, and `%x.1.3.A`
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; all denote the sequence of terminals [1, 3, 10];
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; (ii) binary, decimal, or hexadecimal ranges,
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; e.g. `%x30-39` denotes any singleton sequence of terminals
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; [_n_] with 48 <= _n_ <= 57 (an ASCII digit);
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; (iii) case-sensitive ASCII strings,
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; e.g. `%s"Ab"` denotes the sequence of terminals [65, 98];
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; and (iv) case-insensitive ASCII strings,
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; e.g. `%i"ab"`, or just `"ab"`, denotes
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; any sequence of terminals among
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; [65, 66],
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; [65, 98],
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; [97, 66], and
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; [97, 98].
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; ABNF terminals in suitable sets represent ASCII or Unicode characters.
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; ABNF allows repetition prefixes `n*m`,
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; where `n` and `m` are natural numbers in decimal notation;
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; if absent,
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; `n` defaults to 0, and
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; `m` defaults to infinity.
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; For example,
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; `1*4HEXDIG` denotes one to four `HEXDIG`s,
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; `*3DIGIT` denotes up to three `DIGIT`s, and
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; `1*OCTET` denotes one or more `OCTET`s.
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; A single `n` prefix
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; abbreviates `n*n`,
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; e.g. `3DIGIT` denotes three `DIGIT`s.
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; Instead of BNF's `|`, ABNF uses `/` to separate alternatives.
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; Repetition prefixes have precedence over juxtapositions,
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; which have precedence over `/`.
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; Round brackets group things and override the aforementioned precedence rules,
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; e.g. `*(WSP / CRLF WSP)` denotes sequences of terminals
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; obtained by repeating, zero or more times,
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; either (i) a `WSP` or (ii) a `CRLF` followed by a `WSP`.
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; Square brackets also group things but make them optional,
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; e.g. `[":" port]` is equivalent to `0*1(":" port)`.
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; Instead of BNF's `::=`, ABNF uses `=` to define nonterminals,
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; and `=/` to incrementally add alternatives
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; to previously defined nonterminals.
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; For example, the rule `BIT = "0" / "1"`
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; is equivalent to `BIT = "0"` followed by `BIT =/ "1"`.
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; The syntax of ABNF itself is formally specified in ABNF
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; (in Section 4 of the aforementioned RFC 5234,
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; after the syntax and semantics of ABNF
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; are informally specified in natural language
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; (in Sections 1, 2, and 3 of the aforementioned RFC 5234).
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; The syntax rules of ABNF prescribe the ASCII codes allowed for
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; white space (spaces and horizontal tabs),
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; line endings (carriage returns followed by line feeds),
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; and comments (semicolons to line endings).
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; Structure
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; ---------
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; This ABNF grammar consists of two (sub-)grammars:
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; (i) a lexical grammar that describes how
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; sequence of characters are parsed into tokens, and
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; (ii) a syntactic grammar that describes how
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; tokens are parsed into expressions, statements, etc.
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; The adjectives 'lexical' and 'syntactic' are
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; the same ones used in the Java language reference,
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; for instance;
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; alternative terms may be used in other languages,
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; but the separation into these two components is quite common
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; (the situation is sometimes a bit more complex, with multiple passes,
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; e.g. Unicode escape processing in Java).
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; This separation enables
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; concerns of white space, line endings, etc.
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; to be handled by the lexical grammar,
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; with the syntactic grammar focused on the more important structure.
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; Handling both aspects in a single grammar may be unwieldy,
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; so having two grammars provides more clarity and readability.
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; ABNF is a context-free grammar notation, with no procedural interpretation.
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; The two grammars conceptually define two subsequent processing phases,
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; as detailed below.
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; However, a parser implementation does not need to perform
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; two strictly separate phases (in fact, it typically does not),
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; so long as it produces the same final result.
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; The grammar is accompanied by some extra-grammatical requirements,
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; which are not conveniently expressible in a context-free grammar like ABNF.
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; These requirements are needed to make the grammar unambiguous,
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; i.e. to ensure that, for each sequence of terminals,
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; there is exactly one parse tree for that sequence terminals
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; that satisfies not only the grammar rules
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; but also the extra-grammatical requirements.
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; These requirements are expressed as comments in this file.
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; Operator Precedence
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; -------------------
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; We formulate the grammar rules for expressions
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; in a way that describes the relative precedence of operators,
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; as often done in language syntax specifications.
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; For instance, consider the rules
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;
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; multiplicative-expression =
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; exponential-expression
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; / multiplicative-expression "*" exponential-expression
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; / multiplicative-expression "/" exponential-expression
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;
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; additive-expression =
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; multiplicative-expression
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; / additive-expression "+" multiplicative-expression
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; / additive-expression "-" multiplicative-expression
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;
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; These rules tell us
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; that the additive operators `+` and `-` have lower precedence
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; than the multiplicative operators `*` and `/`,
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; and that both the additive and multiplicative operators associate to the left.
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; This may be best understood via the examples given below.
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; According to the rules, the expression
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;
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; x + y * z
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;
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; can only be parsed as
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;
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; +
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; / \
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; x *
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; / \
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; y z
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;
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; and not as
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;
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; *
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; / \
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; + z
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; / \
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; x y
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;
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; because a multiplicative expression cannot have an additive expression
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; as first sub-expression, as it would in the second tree above.
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; Also according to the rules, the expression
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;
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; x + y + z
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;
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; can only be parsed as
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;
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; +
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; / \
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; + z
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; / \
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; x y
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;
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; and not as
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;
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; +
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; / \
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; x +
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; / \
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; y z
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;
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; because an additive expression cannot have an additive expression
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; as second sub-expression, as it would in the second tree above.
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; Naming Convention
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; -----------------
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; This ABNF grammar uses nonterminal names
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; that consist of complete English words, separated by dashes,
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; and that describe the construct the way it is in English.
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; For instance, we use the name `conditional-statement`
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; to describe conditional statements.
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; At the same time, this grammar establishes
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; a precise and official nomenclature for the Leo constructs,
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; by way of the nonterminal names that define their syntax.
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; For instance, the rule
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;
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; group-literal = product-group-literal
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; / affine-group-literal
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;
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; tells us that there are two kinds of group literals,
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; namely product group literals and affine group literals.
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; This is more precise than describing them as
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; integers (which are not really group elements per se),
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; or points (they are all points, just differently specified),
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; or being singletons vs. pairs (which is a bit generic).
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; The only exception to the nomenclature-establishing role of the grammar
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; is the fact that, as discussed above,
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; we write the grammar rules in a way that determines
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; the relative precedence and the associativity of expression operators,
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; and therefore we have rules like
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;
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; unary-expression = primary-expression
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; / "!" unary-expression
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; / "-" unary-expression
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;
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; In order to allow the recursion of the rule to stop,
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; we need to regard, in the grammar, a primary expression as a unary expression
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; (i.e. a primary expression is also a unary expression in the grammar;
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; but note that the opposite is not true).
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; However, this is just a grammatical artifact:
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; ontologically, a primary expression is not really a unary expression,
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; because a unary expression is one that consists of
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; a unary operator and an operand sub-expression.
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; These terminological exceptions should be easy to identify in the rules.
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; Lexical Grammar
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; ---------------
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; A Leo file is a finite sequence of Unicode characters,
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; represented as Unicode code points,
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; which are numbers in the range from 0 to 10FFFF.
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; These are captured by the ABNF rule `character` below.
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; The lexical grammar defines how, at least conceptually,
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; the sequence of characters is turned into
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; a sequence of tokens, comments, and whitespaces:
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; these entities are all defined by the grammar rules below.
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; As stated, the lexical grammar alone is ambiguous.
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; For example, the sequence of characters `**` (i.e. two stars)
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; could be equally parsed as two `*` symbol tokens or one `**` symbol token
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; (see rule for `symbol` below).
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; As another example, the sequence or characters `<CR><LF>`
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; (i.e. carriage return followed by line feed)
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; could be equally parsed as two line terminators or one
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; (see rule for `newline`).
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; Thus, as often done in language syntax definitions,
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; the lexical grammar is disambiguated by
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; the extra-grammatical requirement that
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; the longest possible sequence of characters is always parsed.
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; This way, `**` must be parsed as one `**` symbol token,
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; and `<CR><LF>` must be parsed as one line terminator.
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; As mentioned above, a character is any Unicode code point.
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; This grammar does not say how those are encoded in files (e.g. UTF-8):
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; it starts with a decoded sequence of Unicode code points.
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; Note that we allow any value,
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; even though some values may not be used according to the Unicode standard.
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character = %x0-10FFFF ; any Unicode code point
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; We give names to certain ASCII characters.
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horizontal-tab = %x9 ; <HT>
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line-feed = %xA ; <LF>
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carriage-return = %xD ; <CR>
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space = %x20 ; <SP>
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double-quote = %x22 ; "
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single-quote = %x27 ; '
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; We give names to complements of certain ASCII characters.
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; These consist of all the Unicode characters except for one or two.
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not-star = %x0-29 / %x2B-10FFFF ; anything but *
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not-star-or-slash = %x0-29 / %x2B-2E / %x30-10FFFF
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; anything but * or /
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not-line-feed-or-carriage-return = %x0-9 / %xB-C / %xE-10FFFF
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; anything but <LF> or <CR>
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not-double-quote-or-backslash = %x0-21 / %x23-5B / %x5D-10FFFF
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; anything but " or \
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not-single-quote-or-backslash = %x0-26 / %x28-5B / %x5D-10FFFF
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; anything but ' or \
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; Lines in Leo may be terminated via
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; a single carriage return,
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; a line feed,
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; or a carriage return immediately followed by a line feed.
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; Note that the latter combination constitutes a single line terminator,
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; according to the extra-grammatical requirement of the longest sequence,
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; described above.
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newline = line-feed / carriage-return / carriage-return line-feed
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; Line terminators form whitespace, along with spaces and horizontal tabs.
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whitespace = space / horizontal-tab / newline
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; There are two kinds of comments in Leo, as in other languages.
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; One is block comments of the form `/* ... */`,
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; and the other is end-of-line comments of the form `// ...`.
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; The first kind start at `/*` and end at the first `*/`,
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; possibly spanning multiple (partial) lines;
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; these do no nest.
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; The second kind start at `//` and extend till the end of the line.
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; The rules about comments given below are similar to
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; the ones used in the Java language reference.
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comment = block-comment / end-of-line-comment
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block-comment = "/*" rest-of-block-comment
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rest-of-block-comment = "*" rest-of-block-comment-after-star
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/ not-star rest-of-block-comment
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rest-of-block-comment-after-star = "/"
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/ "*" rest-of-block-comment-after-star
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/ not-star-or-slash rest-of-block-comment
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end-of-line-comment = "//" *not-line-feed-or-carriage-return newline
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; Below are the keywords in the Leo language.
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; They cannot be used as identifiers.
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keyword = %s"address"
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/ %s"as"
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/ %s"bool"
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/ %s"char"
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/ %s"circuit"
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/ %s"console"
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/ %s"const"
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/ %s"else"
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/ %s"false"
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/ %s"field"
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/ %s"for"
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/ %s"function"
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/ %s"group"
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/ %s"i8"
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/ %s"i16"
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/ %s"i32"
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/ %s"i64"
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/ %s"i128"
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/ %s"if"
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/ %s"import"
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/ %s"in"
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/ %s"input"
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/ %s"let"
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/ %s"mut"
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/ %s"return"
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/ %s"Self"
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/ %s"self"
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/ %s"static"
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/ %s"string"
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/ %s"true"
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/ %s"u8"
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/ %s"u16"
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/ %s"u32"
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/ %s"u64"
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/ %s"u128"
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; The following rules define (ASCII)
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; digits and (uppercase and lowercase) letters.
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digit = %x30-39 ; 0-9
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uppercase-letter = %x41-5A ; A-Z
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lowercase-letter = %x61-7A ; a-z
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letter = uppercase-letter / lowercase-letter
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; The following rules defines (ASCII) octal and hexadecimal digits.
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; Note that the latter are case-insensitive.
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octal-digit = %x30-37 ; 0-7
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hexadecimal-digit = digit / "a" / "b" / "c" / "d" / "e" / "f"
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; An identifier is a non-empty sequence of letters, digits, and underscores,
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; starting with a letter.
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; It must not be a keyword: this is an extra-grammatical requirement.
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; It must also not be or start with `aleo1`,
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; because that is used for address literals:
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; this is another extra-grammatical requirement.
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identifier = letter *( letter / digit / "_" ) ; but not a keyword or aleo1...
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; A package name consists of one or more segments separated by single dashes,
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; where each segment is a non-empty sequence of lowercase letters and digits.
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package-name = 1*( lowercase-letter / digit )
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*( "-" 1*( lowercase-letter / digit ) )
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; Annotations have names, which are identifiers immediately preceded by `@`.
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annotation-name = "@" identifier
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; A natural (number) is a sequence of one or more digits.
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; We allow leading zeros, e.g. `007`.
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natural = 1*digit
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; An integer (number) is either a natural or its negation.
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; We allow leading zeros also in negative numbers, e.g. `-007`.
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integer = [ "-" ] natural
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; An untyped literal is just an integer.
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untyped-literal = integer
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; Unsigned literals are naturals followed by unsigned types.
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unsigned-literal = natural ( %s"u8" / %s"u16" / %s"u32" / %s"u64" / %s"u128" )
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; Signed literals are integers followed by signed types.
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signed-literal = integer ( %s"i8" / %s"i16" / %s"i32" / %s"i64" / %s"i128" )
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; Field literals are integers followed by the type of field elements.
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field-literal = integer %s"field"
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; There are two kinds of group literals.
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; One is a single integer followed by the type of group elements,
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; which denotes the scalar product of the generator point by the integer.
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; The other kind is not a token because it allows some whitespace inside;
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; therefore, it is defined in the syntactic grammar.
|
|
|
|
product-group-literal = integer %s"group"
|
|
|
|
; Boolean literals are the usual two.
|
|
|
|
boolean-literal = %s"true" / %s"false"
|
|
|
|
; An address literal starts with `aleo1`
|
|
; and continues with exactly 58 lowercase letters and digits.
|
|
; Thus an address always consists of 63 characters.
|
|
|
|
address-literal = %s"aleo1" 58( lowercase-letter / digit )
|
|
|
|
; A character literal consists of an element surrounded by single quotes.
|
|
; The element is any character other than single quote or backslash,
|
|
; or an escape, which starts with backslash.
|
|
; There are simple escapes with a single character,
|
|
; ASCII escapes with an octal and a hexadecimal digit
|
|
; (which together denote a number between 0 and 127),
|
|
; and Unicode escapes with one to six hexadecimal digits
|
|
; (which must not exceed 10FFFF).
|
|
|
|
character-literal = single-quote character-literal-element single-quote
|
|
|
|
character-literal-element = not-single-quote-or-backslash
|
|
/ simple-character-escape
|
|
/ ascii-character-escape
|
|
/ unicode-character-escape
|
|
|
|
single-quote-escape = "\" single-quote ; \'
|
|
|
|
double-quote-escape = "\" double-quote ; \"
|
|
|
|
backslash-escape = "\\"
|
|
|
|
line-feed-escape = %s"\n"
|
|
|
|
carriage-return-escape = %s"\r"
|
|
|
|
horizontal-tab-escape = %s"\t"
|
|
|
|
null-character-escape = "\0"
|
|
|
|
simple-character-escape = single-quote-escape
|
|
/ double-quote-escape
|
|
/ backslash-escape
|
|
/ line-feed-escape
|
|
/ carriage-return-escape
|
|
/ horizontal-tab-escape
|
|
/ null-character-escape
|
|
|
|
ascii-character-escape = %s"\x" octal-digit hexadecimal-digit
|
|
|
|
unicode-character-escape = %s"\u{" 1*6hexadecimal-digit "}"
|
|
|
|
; A string literal consists of one or more elements surrounded by double quotes.
|
|
; Each element is any character other than double quote or backslash,
|
|
; or an escape among the same ones used for elements of character literals.
|
|
; There must be at least one element
|
|
; because string literals denote character arrays,
|
|
; and arrays must not be empty.
|
|
|
|
string-literal = double-quote 1*string-literal-element double-quote
|
|
|
|
string-literal-element = not-double-quote-or-backslash
|
|
/ simple-character-escape
|
|
/ ascii-character-escape
|
|
/ unicode-character-escape
|
|
|
|
; The ones above are all the atomic literals
|
|
; (in the sense that they are tokens, without whitespace allowed in them),
|
|
; as defined by the following rule.
|
|
|
|
atomic-literal = untyped-literal
|
|
/ unsigned-literal
|
|
/ signed-literal
|
|
/ field-literal
|
|
/ product-group-literal
|
|
/ boolean-literal
|
|
/ address-literal
|
|
/ character-literal
|
|
/ string-literal
|
|
|
|
; After defining the (mostly) alphanumeric tokens above,
|
|
; it remains to define tokens for non-alphanumeric symbols such as `+` and `(`.
|
|
; Different programming languages used different terminologies for these,
|
|
; e.g. operators, separators, punctuators, etc.
|
|
; Here we use `symbol`, for all of them.
|
|
; We also include a token consisting of
|
|
; a closing parenthesis `)` immediately followed by `group`:
|
|
; as defined in the syntactic grammar,
|
|
; this is the final part of an affine group literal;
|
|
; even though it includes letters,
|
|
; it seems appropriate to still consider it a symbol,
|
|
; particularly since it starts with a proper symbol.
|
|
|
|
symbol = "!" / "&&" / "||"
|
|
/ "==" / "!="
|
|
/ "<" / "<=" / ">" / ">="
|
|
/ "+" / "-" / "*" / "/" / "**"
|
|
/ "=" / "+=" / "-=" / "*=" / "/=" / "**="
|
|
/ "(" / ")"
|
|
/ "[" / "]"
|
|
/ "{" / "}"
|
|
/ "," / "." / ".." / "..." / ";" / ":" / "::" / "?"
|
|
/ "->" / "_"
|
|
/ %s")group"
|
|
|
|
; Everything defined above, other than comments and whitespace,
|
|
; is a token, as defined by the following rule.
|
|
|
|
token = keyword
|
|
/ identifier
|
|
/ atomic-literal
|
|
/ package-name
|
|
/ annotation-name
|
|
/ symbol
|
|
|
|
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
|
|
|
; Syntactic Grammar
|
|
; -----------------
|
|
|
|
; The processing defined by the lexical grammar above
|
|
; turns the initial sequence of characters
|
|
; into a sequence of tokens, comments, and whitespaces.
|
|
; The purpose of comments and whitespaces, from a syntactic point of view,
|
|
; is just to separate tokens:
|
|
; they are discarded, leaving a sequence of tokens.
|
|
; The syntactic grammar describes how to turn
|
|
; a sequence of tokens into concrete syntax trees.
|
|
|
|
; There are unsigned and signed integer types, for five sizes.
|
|
|
|
unsigned-type = %s"u8" / %s"u16" / %s"u32" / %s"u64" / %s"u128"
|
|
|
|
signed-type = %s"i8" / %s"i16" / %s"i32" / %s"i64" / %s"i128"
|
|
|
|
integer-type = unsigned-type / signed-type
|
|
|
|
; The integer types, along with the field and group types,
|
|
; for the arithmetic types, i.e. the ones that support arithmetic operations.
|
|
|
|
field-type = %s"field"
|
|
|
|
group-type = %s"group"
|
|
|
|
arithmetic-type = integer-type / field-type / group-type
|
|
|
|
; The arithmetic types, along with the boolean, address, and character types,
|
|
; form the scalar types, i.e. the ones whose values do not contain (sub-)values.
|
|
|
|
boolean-type = %s"bool"
|
|
|
|
address-type = %s"address"
|
|
|
|
character-type = %s"char"
|
|
|
|
scalar-type = boolean-type / arithmetic-type / address-type / character-type
|
|
|
|
; Circuit types are denoted by identifiers and the keyword `Self`.
|
|
; The latter is only allowed inside a circuit definition,
|
|
; to denote the circuit being defined.
|
|
|
|
self-type = %s"Self"
|
|
|
|
circuit-type = identifier / self-type
|
|
|
|
; A tuple type consists of zero, two, or more component types.
|
|
|
|
tuple-type = "(" [ type 1*( "," type ) ] ")"
|
|
|
|
; An array type consists of an element type
|
|
; and an indication of dimensions.
|
|
; There is either a single dimension,
|
|
; or a tuple of one or more dimensions.
|
|
|
|
array-type = "[" type ";" array-dimensions "]"
|
|
|
|
array-dimensions = natural
|
|
/ "(" natural *( "," natural ) ")"
|
|
|
|
; Circuit, tuple, and array types form the aggregate types,
|
|
; i.e. types whose values contain (sub-)values
|
|
; (with the corner-case exception of the empty tuple value).
|
|
|
|
aggregate-type = tuple-type / array-type / circuit-type
|
|
|
|
; Scalar and aggregate types form all the types.
|
|
|
|
type = scalar-type / aggregate-type
|
|
|
|
; The lexical grammar given earlier defines product group literals.
|
|
; The other kind of group literal is a pair of integer coordinates,
|
|
; which are reduced modulo the prime to identify a point,
|
|
; which must be on the elliptic curve.
|
|
; It is also allowed to omit one coordinate (not both),
|
|
; with an indication of how to fill in the missing coordinate
|
|
; (i.e. sign high, sign low, or inferred).
|
|
; This is an affine group literal,
|
|
; because it consists of affine point coordinates.
|
|
|
|
group-coordinate = integer / "+" / "-" / "_"
|
|
|
|
affine-group-literal = "(" group-coordinate "," group-coordinate %s")group"
|
|
|
|
; A literal is either an atomic one or an affine group literal.
|
|
|
|
literal = atomic-literal / affine-group-literal
|
|
|
|
; The following rule is not directly referenced in the rules for expressions
|
|
; (which reference `literal` instead),
|
|
; but it is useful to establish terminology:
|
|
; a group literal is either a product group literal or an affine group literal.
|
|
|
|
group-literal = product-group-literal / affine-group-literal
|
|
|
|
; As often done in grammatical language syntax specifications,
|
|
; we define rules for different kinds of expressions,
|
|
; which also defines the relative precedence
|
|
; of operators and other expression constructs,
|
|
; and the (left or right) associativity of binary operators.
|
|
|
|
; The primary expressions are self-contained in a way,
|
|
; i.e. they have clear delimitations:
|
|
; Some consist of single tokens,
|
|
; while others have explicit endings.
|
|
; Primary expressions also include parenthesized expressions,
|
|
; i.e. any expression may be turned into a primary one
|
|
; by putting parentheses around it.
|
|
|
|
primary-expression = identifier
|
|
/ %s"self"
|
|
/ %s"input"
|
|
/ literal
|
|
/ "(" expression ")"
|
|
/ tuple-expression
|
|
/ array-expression
|
|
/ circuit-expression
|
|
|
|
; Tuple expressions construct tuples.
|
|
; Each consists of zero, two, or more component expressions.
|
|
|
|
tuple-construction = "(" [ expression 1*( "," expression ) ] ")"
|
|
|
|
tuple-expression = tuple-construction
|
|
|
|
; Array expressions construct arrays.
|
|
; There are two kinds:
|
|
; one lists the element expressions (at least one),
|
|
; including spreads (via `...`) which are arrays being spliced in;
|
|
; the other repeats (the value of) a single expression
|
|
; across one or more dimensions.
|
|
|
|
array-inline-construction = "["
|
|
array-inline-element
|
|
*( "," array-inline-element )
|
|
"]"
|
|
|
|
array-inline-element = expression / "..." expression
|
|
|
|
array-repeat-construction = "[" expression ";" array-dimensions "]"
|
|
|
|
array-construction = array-inline-construction / array-repeat-construction
|
|
|
|
array-expression = array-construction
|
|
|
|
; Circuit expressions construct circuit values.
|
|
; Each lists values for all the member variables (in any order);
|
|
; there must be at least one member variable.
|
|
; A single identifier abbreviates
|
|
; a pair consisting of the same identifier separated by colon;
|
|
; note that, in the expansion, the left one denotes a member name,
|
|
; while the right one denotes an expression (a variable),
|
|
; so they are syntactically identical but semantically different.
|
|
|
|
circuit-construction = circuit-type "{"
|
|
circuit-inline-element
|
|
*( "," circuit-inline-element ) [ "," ]
|
|
"}"
|
|
|
|
circuit-inline-element = identifier ":" expression / identifier
|
|
|
|
circuit-expression = circuit-construction
|
|
|
|
; After primary expressions, postfix expressions have highest precedence.
|
|
; They apply to primary expressions, and recursively to postfix expressions.
|
|
|
|
; There are postfix expressions to access parts of aggregate values.
|
|
; A tuple access selects a component by index (zero-based).
|
|
; There are two kinds of array accesses:
|
|
; one selects a single element by index (zero-based);
|
|
; the other selects a range via two indices,
|
|
; the first inclusive and the second exclusive --
|
|
; both are optional,
|
|
; the first defaulting to 0 and the second to the array length.
|
|
; A circuit access selects a member variable by name.
|
|
|
|
; Function calls are also postfix expressions.
|
|
; There are three kinds of function calls:
|
|
; top-level function calls,
|
|
; instance (i.e. non-static) member function calls, and
|
|
; static member function calls.
|
|
; What changes is the start, but they all end in an argument list.
|
|
|
|
function-arguments = "(" [ expression *( "," expression ) ] ")"
|
|
|
|
postfix-expression = primary-expression
|
|
/ postfix-expression "." natural
|
|
/ postfix-expression "." identifier
|
|
/ identifier function-arguments
|
|
/ postfix-expression "." identifier function-arguments
|
|
/ circuit-type "::" identifier function-arguments
|
|
/ postfix-expression "[" expression "]"
|
|
/ postfix-expression "[" [expression] ".." [expression] "]"
|
|
|
|
; Unary operators have the highest operator precedence.
|
|
; They apply to postfix expressions,
|
|
; and recursively to unary expressions.
|
|
|
|
unary-expression = postfix-expression
|
|
/ "!" unary-expression
|
|
/ "-" unary-expression
|
|
|
|
; Next in the operator precedence is exponentiation,
|
|
; following mathematical practice.
|
|
; The current rule below makes exponentiation right-associative,
|
|
; i.e. `a ** b ** c` must be parsed as `a ** (b ** c)`.
|
|
|
|
exponential-expression = unary-expression
|
|
/ unary-expression "**" exponential-expression
|
|
|
|
; Next in precedence come multiplication and division, both left-associative.
|
|
|
|
multiplicative-expression = exponential-expression
|
|
/ multiplicative-expression "*" exponential-expression
|
|
/ multiplicative-expression "/" exponential-expression
|
|
|
|
; Then there are addition and subtraction, both left-assocative.
|
|
|
|
additive-expression = multiplicative-expression
|
|
/ additive-expression "+" multiplicative-expression
|
|
/ additive-expression "-" multiplicative-expression
|
|
|
|
; Next in the precedence order are ordering relations.
|
|
; These are not associative, because they return boolean values.
|
|
|
|
ordering-expression = additive-expression
|
|
/ additive-expression "<" additive-expression
|
|
/ additive-expression ">" additive-expression
|
|
/ additive-expression "<=" additive-expression
|
|
/ additive-expression ">=" additive-expression
|
|
|
|
; Equalities return booleans but may also operate on booleans;
|
|
; the rule below makes them left-associative.
|
|
|
|
equality-expression = ordering-expression
|
|
/ equality-expression "==" ordering-expression
|
|
/ equality-expression "!=" ordering-expression
|
|
|
|
; Next come conjunctive expressions, left-associative.
|
|
|
|
conjunctive-expression = equality-expression
|
|
/ conjunctive-expression "&&" equality-expression
|
|
|
|
; Next come disjunctive expressions, left-associative.
|
|
|
|
disjunctive-expression = conjunctive-expression
|
|
/ disjunctive-expression "||" conjunctive-expression
|
|
|
|
; Finally we have conditional expressions.
|
|
|
|
conditional-expression = disjunctive-expression
|
|
/ conditional-expression
|
|
"?" expression
|
|
":" conditional-expression
|
|
|
|
; Those above are all the expressions.
|
|
; Recall that conditional expressions
|
|
; may be disjunctive expressions,
|
|
; which may be conjunctive expressions,
|
|
; and so on all the way to primary expressions.
|
|
|
|
expression = conditional-expression
|
|
|
|
; There are various kinds of statements, including blocks.
|
|
; Blocks are possibly empty sequences of statements surrounded by curly braces.
|
|
|
|
statement = expression-statement
|
|
/ return-statement
|
|
/ variable-declaration
|
|
/ constant-declaration
|
|
/ conditional-statement
|
|
/ loop-statement
|
|
/ assignment-statement
|
|
/ console-statement
|
|
/ block
|
|
|
|
block = "{" *statement "}"
|
|
|
|
; An expression (that must return the empty tuple, as semantically required)
|
|
; can be turned into a statement by appending a semicolon.
|
|
|
|
expression-statement = expression ";"
|
|
|
|
; A return statement always takes an expression, and ends with a semicolon.
|
|
|
|
return-statement = %s"return" expression ";"
|
|
|
|
; There are variable declarations and constant declarations,
|
|
; which only differ in the starting keyword.
|
|
; These declarations are also statements.
|
|
; The names of the variables or constants are
|
|
; either a single one or a tuple of two or more;
|
|
; in all cases, there is just one optional type
|
|
; and just one initializing expression.
|
|
|
|
variable-declaration = %s"let" identifier-or-identifiers [ ":" type ]
|
|
"=" expression ";"
|
|
|
|
constant-declaration = %s"const" identifier-or-identifiers [ ":" type ]
|
|
"=" expression ";"
|
|
|
|
identifier-or-identifiers = identifier
|
|
/ "(" identifier 1*( "," identifier ) ")"
|
|
|
|
; A conditional statement always starts with a condition and a block
|
|
; (which together form a branch).
|
|
; It may stop there, or it may continue with an alternative block,
|
|
; or possibly with another conditional statement, forming a chain.
|
|
; Note that blocks are required in all branches, not merely statements.
|
|
|
|
branch = %s"if" expression block
|
|
|
|
conditional-statement = branch
|
|
/ branch %s"else" block
|
|
/ branch %s"else" conditional-statement
|
|
|
|
; A loop statement implicitly defines a loop variable
|
|
; that goes from a starting value (inclusive) to an ending value (exclusive).
|
|
; The body is a block.
|
|
|
|
loop-statement = %s"for" identifier %s"in" expression ".." expression block
|
|
|
|
; An assignment statement is straightforward.
|
|
; Based on the operator, the assignment may be simple (i.e. `=`)
|
|
; or compound (i.e. combining assignment with an arithmetic operation).
|
|
|
|
assignment-operator = "=" / "+=" / "-=" / "*=" / "/=" / "**="
|
|
|
|
assignment-statement = expression assignment-operator expression ";"
|
|
|
|
; Console statements start with the `console` keyword,
|
|
; followed by a console function call.
|
|
; The call may be an assertion or a print command.
|
|
; The former takes an expression (which must be boolean) as argument.
|
|
; The latter takes either no argument,
|
|
; or a format string followed by expressions,
|
|
; whose number must match the number of containers `{}` in the format string.
|
|
; Note that the console function names are identifiers, not keywords.
|
|
; There are three kinds of print commands.
|
|
|
|
console-statement = %s"console" "." console-call
|
|
|
|
console-call = assert-call
|
|
/ print-call
|
|
|
|
assert-call = %s"assert" "(" expression ")"
|
|
|
|
print-function = %s"debug" / %s"error" / %s"log"
|
|
|
|
print-arguments = "(" [ string-literal *( "," expression ) ] ")"
|
|
|
|
print-call = print-function print-arguments
|
|
|
|
; An annotation consists of an annotation name (which starts with `@`)
|
|
; with optional annotation arguments, which are identifiers.
|
|
; Note that no parentheses are used if there are no arguments.
|
|
|
|
annotation = annotation-name
|
|
[ "(" identifier *( "," identifier ) ")" ]
|
|
|
|
; A function declaration defines a function.
|
|
; The output type is optional, defaulting to the empty tuple type.
|
|
; In general, a function input consists of an identifier and a type,
|
|
; with an optional 'const' modifier.
|
|
; Additionally, functions inside circuits
|
|
; may start with a `mut self` or `const self` or `self` parameter.
|
|
|
|
function-declaration = *annotation %s"function" identifier
|
|
"(" [ function-parameters ] ")" [ "->" type ]
|
|
block
|
|
|
|
function-parameters = self-parameter
|
|
/ self-parameter "," function-inputs
|
|
/ function-inputs
|
|
|
|
self-parameter = [ %s"mut" / %s"const" ] %s"self"
|
|
|
|
function-inputs = function-input *( "," function-input )
|
|
|
|
function-input = [ %s"const" ] identifier ":" type
|
|
|
|
; A circuit member variable declaration consists of
|
|
; an identifier and a type, terminated by semicolon.
|
|
; For backward compatibility,
|
|
; member variable declarations may be alternatively followed by commas,
|
|
; and the last one may not be followed by anything:
|
|
; these are deprecated, and will be eventually removed,
|
|
; leaving only mandatory semicolons.
|
|
; Note that there is no rule for a single `member-variable-declaration`,
|
|
; but instead one for a sequence of them;
|
|
; see the rule `circuit-declaration`.
|
|
|
|
member-variable-declarations = *( identifier ":" type ( "," / ";" ) )
|
|
identifier ":" type ( [ "," ] / ";" )
|
|
|
|
; A circuit member function declaration consists of a function declaration.
|
|
|
|
member-function-declaration = function-declaration
|
|
|
|
; A circuit declaration defines a circuit type,
|
|
; as consisting of member variables and functions.
|
|
; To more simply accommodate the backward compatibility
|
|
; described for the rule `member-variable-declarations`,
|
|
; all the member variables must precede all the member functions;
|
|
; this may be relaxed after the backward compatibility is removed,
|
|
; allowing member variables and member functions to be intermixed.
|
|
|
|
circuit-declaration = *annotation %s"circuit" identifier
|
|
"{" [ member-variable-declarations ]
|
|
*member-function-declaration "}"
|
|
|
|
; An import declaration consists of the `import` keyword
|
|
; followed by a package path, which may be one of the following:
|
|
; a single wildcard;
|
|
; an identifier, optionally followed by a local renamer;
|
|
; a package name followed by a path, recursively;
|
|
; or a parenthesized list of package paths,
|
|
; which are "fan out" of the initial path.
|
|
; Note that we allow the last element of the parenthesized list
|
|
; to be followed by a comma, for convenience.
|
|
; The package path in the import declaration must start with a package name
|
|
; (e.g. it cannot be a `*`):
|
|
; the rule for import declaration expresses this requirement
|
|
; by using an explicit package name before the package path.
|
|
|
|
import-declaration = %s"import" package-name "." package-path ";"
|
|
|
|
package-path = "*"
|
|
/ identifier [ %s"as" identifier ]
|
|
/ package-name "." package-path
|
|
/ "(" package-path *( "," package-path ) [","] ")"
|
|
|
|
; Finally, we define a file as a sequence of zero or more declarations.
|
|
; We allow constant declarations at the top level, for global constants.
|
|
; Currently variable declarations are disallowed at the top level.
|
|
|
|
declaration = import-declaration
|
|
/ function-declaration
|
|
/ circuit-declaration
|
|
/ constant-declaration
|
|
|
|
file = *declaration
|
|
|
|
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
|
|
|
; Format Note
|
|
; -----------
|
|
|
|
; The ABNF standard requires grammars
|
|
; to consist of lines terminated by `<CR><LF>`
|
|
; (i.e. carriage return followed by line feed, DOS/Windows-style),
|
|
; as explained in the background on ABNF earlier in this file.
|
|
; This file's lines are therefore terminated by `<CR><LF>`.
|
|
; To avoid losing this requirement across systems,
|
|
; this file is marked as `text eol=crlf` in `.gitattributes`:
|
|
; this means that the file is textual, enabling visual diffs,
|
|
; but its lines will always be terminated by `<CR><LF>` on any system.
|
|
|
|
; Note that this `<CR><LF>` requirement only applies
|
|
; to the grammar files themselves.
|
|
; It does not apply to the lines of the languages described by the grammar.
|
|
; ABNF grammars may describe any kind of languages,
|
|
; with any kind of line terminators,
|
|
; or even without line terminators at all (e.g. for "binary" languages).
|