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abnf-grammar.txt | ||
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README.md |
Leo Grammar
Copyright (C) 2021 Aleo Systems Inc.
Introduction
This file contains an ABNF (Augmented Backus-Naur Form) grammar of Leo. Background on ABNF is provided later in this file.
This grammar provides an official definition of the syntax of Leo that is both human-readable and machine-readable. It will be part of an upcoming Leo language reference. It may also be used to generate parser tests at some point.
We are also using this grammar as part of a mathematical formalization of the Leo language, which we are developing in the ACL2 theorem prover and which we plan to publish at some point. In particular, we have used a formally verified parser of ABNF grammars (at https://github.com/acl2/acl2/tree/master/books/kestrel/abnf; also see the paper at https://www.kestrel.edu/people/coglio/vstte18.pdf) to parse this grammar into a formal representation of the Leo concrete syntax and to validate that the grammar satisfies certain consistency properties.
Background on ABNF
ABNF is an Internet standard: see RFC 5234 at https://www.rfc-editor.org/info/rfc5234 and RFC 7405 at https://www.rfc-editor.org/info/rfc7405. It is used to specify the syntax of JSON, HTTP, and other standards.
ABNF adds conveniences and makes slight modifications to Backus-Naur Form (BNF), without going beyond context-free grammars.
Instead of BNF's angle-bracket notation for nonterminals, ABNF uses case-insensitive names consisting of letters, digits, and dashes, e.g. HTTP-message and IPv6address. ABNF includes an angle-bracket notation for prose descriptions, e.g. <host, see [RFC3986], Section 3.2.2>, usable as last resort in the definiens of a nonterminal.
While BNF allows arbitrary terminals, ABNF uses only natural numbers as terminals, and denotes them via: (i) binary, decimal, or hexadecimal sequences, e.g. %b1.11.1010, %d1.3.10, and %x.1.3.A all denote the sequence of terminals '1 3 10'; (ii) binary, decimal, or hexadecimal ranges, e.g. %x30-39 denotes any singleton sequence of terminals 'n' with 48 <= n <= 57 (an ASCII digit); (iii) case-sensitive ASCII strings, e.g. %s"Ab" denotes the sequence of terminals '65 98'; and (iv) case-insensitive ASCII strings, e.g. %i"ab", or just "ab", denotes any sequence of terminals among '65 66', '65 98', '97 66', and '97 98'. ABNF terminals in suitable sets represent ASCII or Unicode characters.
ABNF allows repetition prefixes nm, where n and m are natural numbers in decimal notation; if absent, n defaults to 0, and m defaults to infinity. For example, 14HEXDIG denotes one to four HEXDIGs, 3DIGIT denotes up to three DIGITs, and 1OCTET denotes one or more OCTETs. A single n prefix abbreviates n*n, e.g. 3DIGIT denotes three DIGITs.
Instead of BNF's |, ABNF uses / to separate alternatives. Repetition prefixes have precedence over juxtapositions, which have precedence over /. Round brackets group things and override the aforementioned precedence rules, e.g. (WSP / CRLF WSP) denotes sequences of terminals obtained by repeating, zero or more times, either (i) a WSP or (ii) a CRLF followed by a WSP. Square brackets also group things but make them optional, e.g. [":" port] is equivalent to 01(":" port).
Instead of BNF's ::=, ABNF uses = to define nonterminals, and =/ to incrementally add alternatives to previously defined nonterminals. For example, the rule BIT = "0" / "1" is equivalent to BIT = "0" followed by BIT =/ "1".
The syntax of ABNF itself is formally specified in ABNF (in Section 4 of the aforementioned RFC 5234, after the syntax and semantics of ABNF are informally specified in natural language (in Sections 1, 2, and 3 of the aforementioned RFC 5234). The syntax rules of ABNF prescribe the ASCII codes allowed for white space (spaces and horizontal tabs), line endings (carriage returns followed by line feeds), and comments (semicolons to line endings).
Structure
This ABNF grammar consists of two (sub-)grammars: (i) a lexical grammar that describes how sequence of characters are parsed into tokens, and (ii) a syntactic grammar that described how tokens are parsed into expressions, statements, etc. The adjectives 'lexical' and 'syntactic' are the same ones used in the Java language reference, for instance; alternative terms may be used in other languages, but the separation into these two components is quite common (the situation is sometimes a bit more complex, with multiple passes, e.g. Unicode escape processing in Java).
This separation enables concerns of white space, line endings, etc. to be handled by the lexical grammar, with the syntactic grammar focused on the more important structure. Handling both aspects in a single grammar may be unwieldy, so having two grammars provides more clarity and readability.
ABNF is a context-free grammar notation, with no procedural interpretation. The two grammars conceptually define two subsequent processing phases, as detailed below. However, a parser implementation does not need to perform two strictly separate phases (in fact, it typically does not), so long as it produces the same final result.
The grammar is accompanied by some extra-grammatical requirements, which are not conveniently expressible in a context-free grammar like ABNF. These requirements are needed to make the grammar unambiguous, i.e. to ensure that, for each sequence of terminals, there is exactly one parse tree for that sequence terminals that satisfies not only the grammar rules but also the extra-grammatical requirements. These requirements are expressed as comments in this file.
Operator Precedence
We formulate the grammar rules for expressions in a way that describes the relative precedence of operators, as often done in language syntax specifications.
For instance, consider the rules
multiplicative-expression =
exponential-expression
/ multiplicative-expression "*" exponential-expression
/ multiplicative-expression "/" exponential-expression
additive-expression =
multiplicative-expression
/ additive-expression "+" multiplicative-expression
/ additive-expression "-" multiplicative-expression
These rules tell us that the additive operators '+' and '-' have lower precedence than the multiplicative operators '*' and '/', and that both the additive and multiplicative operators associate to the left. This may be best understood via the examples given below.
According to the rules, the expression
x + y * z
can only be parsed as
+
/ \
x *
/ \
y z
and not as
*
/ \
+ z
/ \
x y
because a multiplicative expression cannot have an additive expression as first sub-expression, as it would in the second tree above.
Also according to the rules, the expression
x + y + z
can only be parsed as
+
/ \
+ z
/ \
x y
and not as
+
/ \
x +
/ \
y z
because an additive expression cannot have an additive expression as second sub-expression, as it would in the second tree above.
Naming Convention
This ABNF grammar uses nonterminal names that consist of complete English words, separated by dashes, and that describe the construct the way it is in English. For instance, we use the name 'conditional-statement' to describe conditional statements.
At the same time, this grammar establishes a precise and official nomenclature for the Leo constructs, by way of the nonterminal names that define their syntax. For instance, the rule
group-literal = product-group-literal
/ affine-group-literal
tells us that there are two kinds of group literals, namely product group literals and affine group literals. This is more precise than describing them as integers (which are not really group elements per se), or points (they are all points, just differently specified), or being singletons vs. pairs (which is a bit generic).
The only exception to the nomenclature-establishing role of the grammar is the fact that, as discussed above, we write the grammar rules in a way that determines the relative precedence and the associativity of expression operators, and therefore we have rules like
unary-expression = primary-expression
/ "!" unary-expression
/ "-" unary-expression
In order to allow the recursion of the rule to stop, we need to regard, in the grammar, a primary expression as a unary expression (i.e. a primary expression is also a unary expression in the grammar; but note that the opposite is not true). However, this is just a grammatical artifact: ontologically, a primary expression is not really a unary expression, because a unary expression is one that consists of a unary operator and an operand sub-expression. These terminological exceptions should be easy to identify in the rules.
Lexical Grammar
A Leo file is a finite sequence of Unicode characters, represented as Unicode code points, which are numbers in the range form 0 to 10FFFFh. These are captured by the ABNF rule 'character' below.
The lexical grammar defines how, at least conceptually, the sequence of characters is turned into a sequence of tokens, comments, and whitespaces: these entities are all defined by the grammar rules below.
As stated, the lexical grammar alone is ambiguous. For example, the sequence of characters '' (i.e. two stars) could be equally parsed as two '*' symbol tokens or one '' symbol token (see rule for 'symbol' below). As another example, the sequence or characters '' (i.e. carriage return followed by line feed) could be equally parsed as two line terminators or one (see rule for 'newline').
Thus, as often done in language syntax definitions, the lexical grammar is disambiguated by the extra-grammatical requirement that the longest possible sequence of characters is always parsed. This way, '' must be parsed as one '' symbol token, and '' must be parsed as one line terminator.
As mentioned above, a character is any Unicode code point. This grammar does not say how those are encoded in files (e.g. UTF-8): it starts with a decoded sequence of Unicode code points. Note that we allow any value, even though some values may not be used according to the Unicode standard.
character = %x0-10FFFF ; any Unicode code point
We give names to certain ASCII characters.
horizontal-tab = %x9
line-feed = %xA
carriage-return = %xD
space = %x20
double-quote = %x22
We give names to complements of certain ASCII characters. These consist of all the Unicode characters except for one or two.
not-double-quote = %x0-22 / %x24-10FFFF ; anything but "
not-star = %x0-29 / %x2B-10FFFF ; anything but *
not-line-feed-or-carriage-return = %x0-9 / %xB-C / %xE-10FFFF
; anything but LF or CR
not-star-or-slash = %x0-29 / %x2B-2E / %x30-10FFFF ; anything but * or /
Lines in Leo may be terminated via a single carriage return, a line feed, or a carriage return immediately followed by a line feed. Note that the latter combination constitutes a single line terminator, according to the extra-grammatical requirement of the longest sequence, described above.
newline = line-feed / carriage-return / carriage-return line-feed
Go to: line-feed, carriage-return;
Line terminators form whitespace, along with spaces and horizontal tabs.
whitespace = space / horizontal-tab / newline
Go to: newline, space, horizontal-tab;
There are two kinds of comments in Leo, as in other languages. One is block comments of the form '/* ... /', and the other is end-of-line comments of the form '// ...'. The first kind start at '/' and end at the first '*/', possibly spanning multiple (partial) lines; these do no nest. The second kind start at '//' and extend till the end of the line. The rules about comments given below are similar to the ones used in the Java language reference.
comment = block-comment / end-of-line-comment
Go to: end-of-line-comment, block-comment;
block-comment = "/*" rest-of-block-comment
Go to: rest-of-block-comment;
rest-of-block-comment = "*" rest-of-block-comment-after-star
/ not-star rest-of-block-comment
Go to: not-star, rest-of-block-comment-after-star, rest-of-block-comment;
rest-of-block-comment-after-star = "/"
/ "*" rest-of-block-comment-after-star
/ not-star-or-slash rest-of-block-comment
Go to: rest-of-block-comment-after-star, not-star-or-slash, rest-of-block-comment;
end-of-line-comment = "//" *not-line-feed-or-carriage-return newline
Go to: newline;
Below are the keywords in the Leo language. They cannot be used as identifiers.
keyword = %s"address"
/ %s"as"
/ %s"bool"
/ %s"circuit"
/ %s"console"
/ %s"const"
/ %s"else"
/ %s"false"
/ %s"field"
/ %s"for"
/ %s"function"
/ %s"group"
/ %s"i8"
/ %s"i16"
/ %s"i32"
/ %s"i64"
/ %s"i128"
/ %s"if"
/ %s"import"
/ %s"in"
/ %s"input"
/ %s"let"
/ %s"mut"
/ %s"return"
/ %s"Self"
/ %s"self"
/ %s"static"
/ %s"string"
/ %s"true"
/ %s"u8"
/ %s"u16"
/ %s"u32"
/ %s"u64"
/ %s"u128"
The following rules define (ASCII) digits and (uppercase and lowercase) letters.
digit = %x30-39 ; 0-9
uppercase-letter = %x41-5A ; A-Z
lowercase-letter = %x61-7A ; a-z
letter = uppercase-letter / lowercase-letter
Go to: uppercase-letter, lowercase-letter;
An identifier is a non-empty sequence of letters, digits, and underscores, starting with a letter. It must not be a keyword: this is an extra-grammatical constraint.
identifier = letter *( letter / digit / "_" ) ; but not a keyword
Go to: letter;
A package name consists of one or more segments separated by single dashes, where each segment is a non-empty sequence of lowercase letters and digits.
package-name = 1*( lowercase-letter / digit )
*( "-" 1*( lowercase-letter / digit ) )
A format string is a sequence of characters, other than double quote, surrounded by double quotes. Within a format string, sub-strings '{}' are distinguished as containers (these are the ones that may be matched with values whose textual representation replaces the containers in the printed string). There is an implicit extra-grammatical requirements that the explicit 'format-string-container' instances include all the occurrences of '{}' in the parsed character sequence: that is, there may not be two contiguous 'not-double-quote' instances that are '{' and '}'.
format-string-container = "{}"
not-double-quote-or-open-brace = %x0-22 / %x24-7A / %x7C-10FFFF
not-double-quote-or-close-brace = %x0-22 / %x24-7C / %x7E-10FFFF
format-string-element = not-double-quote-or-open-brace
/ "{" not-double-quote-or-close-brace
/ format-string-container
Go to: not-double-quote-or-open-brace, format-string-container, not-double-quote-or-close-brace;
format-string = double-quote *format-string-element double-quote
Go to: double-quote;
Here is (part of this ABNF comment), an alternative way to specify format strings, which captures the extra-grammatical requirement above in the grammar, but is more complicated:
not-double-quote-or-open-brace = %x0-22 / %x24-7A / %x7C-10FFFF
not-double-quote-or-close-brace = %x0-22 / %x24-7C / %x7E-10FFFF
format-string-element = not-double-quote-or-open-brace
/ "{" not-double-quote-or-close-brace
/ format-string-container
format-string = double-quote *format-string-element double-quote
It is not immediately clear which approach is better; there are tradeoffs. We may choose to adopt this one in future revisions of the grammar.
Annotations have names, which are identifiers immediately preceded by '@'.
annotation-name = "@" identifier
Go to: identifier;
A natural (number) is a sequence of one or more digits. We allow leading zeros, e.g. '007'.
natural = 1*digit
An integer (number) is either a natural or its negation. We allow leading zeros also in negative numbers, e.g. '-007'.
integer = [ "-" ] natural
Go to: natural;
An untyped literal is just an integer.
untyped-literal = integer
Go to: integer;
Unsigned literals are naturals followed by unsigned types.
unsigned-literal = natural ( %s"u8" / %s"u16" / %s"u32" / %s"u64" / %s"u128" )
Go to: natural;
Signed literals are integers followed by signed types.
signed-literal = integer ( %s"i8" / %s"i16" / %s"i32" / %s"i64" / %s"i128" )
Go to: integer;
Field literals are integers followed by the type of field elements.
field-literal = integer %s"field"
Go to: integer;
There are two kinds of group literals. One is a single integer followed by the type of group elements, which denotes the scalar product of the generator point by the integer. The other kind is not a token because it allows some whitespace inside; therefore, it is defined in the syntactic grammar.
product-group-literal = integer %s"group"
Go to: integer;
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 )
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
Go to: product-group-literal, untyped-literal, signed-literal, field-literal, boolean-literal, address-literal, unsigned-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.
We could give names to all of these symbols, via rules such as
equality-operator = "=="
and defining 'symbol' in terms of those
symbol = ... / equality-operator / ...
This may or may not make the grammar more readable, but it would help establish a terminology in the grammar, namely the exact names of some of these token. On the other hand, at least some of them are perhaps simple enough that they could be just described in terms of their symbols, e.g. 'double dot', 'question mark', etc.
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
/ format-string
/ annotation-name
/ symbol
Go to: package-name, annotation-name, atomic-literal, format-string, keyword, symbol, identifier;
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
Go to: 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
Go to: integer-type, field-type, group-type;
The arithmetic types, along with the boolean and address types, form the scalar types, i.e. the ones whose values do not contain (sub-)values.
boolean-type = %s"bool"
address-type = %s"address"
scalar-type = boolean-type / arithmetic-type / address-type
Go to: address-type, boolean-type, arithmetic-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
Go to: self-type, identifier;
A tuple type consists of zero, two, or more component types.
tuple-type = "(" [ type 1*( "," type ) ] ")"
Go to: 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 "]"
Go to: array-dimensions, type;
array-dimensions = natural
/ "(" natural *( "," natural ) ")"
Go to: 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
Go to: array-type, circuit-type, tuple-type;
Scalar and aggregate types form all the types.
type = scalar-type / aggregate-type
Go to: 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 / "+" / "-" / "_"
Go to: integer;
affine-group-literal = "(" group-coordinate "," group-coordinate %s")group"
Go to: group-coordinate;
A literal is either an atomic one or an affine group literal.
literal = atomic-literal / affine-group-literal
Go to: affine-group-literal, atomic-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
Go to: 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 deliminations: 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
Go to: identifier, literal, array-expression, expression, tuple-expression, circuit-expression;
Tuple expressions construct tuples. Each consists of zero, two, or more component expressions.
tuple-construction = "(" [ expression 1*( "," expression ) ] ")"
Go to: expression;
tuple-expression = tuple-construction
Go to: 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 )
"]"
Go to: array-inline-element;
array-inline-element = expression / "..." expression
Go to: expression;
array-repeat-construction = "[" expression ";" array-dimensions "]"
Go to: expression, array-dimensions;
array-construction = array-inline-construction / array-repeat-construction
Go to: array-repeat-construction, array-inline-construction;
array-expression = array-construction
Go to: 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 ) [ "," ]
"}"
Go to: circuit-type, circuit-inline-element;
circuit-inline-element = identifier ":" expression / identifier
Go to: identifier, expression;
circuit-expression = circuit-construction
Go to: 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 ) ] ")"
Go to: 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] "]"
Go to: circuit-type, natural, postfix-expression, primary-expression, identifier, function-arguments, 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
Go to: postfix-expression, unary-expression;
Next in the operator precedence is exponentiation, following mathematical practice. The current rule below makes exponentiation left-associative, i.e. 'a ** b ** c' must be parsed as '(a ** b) ** c'.
exponential-expression = unary-expression
/ unary-expression "**" exponential-expression
Go to: 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
Go to: 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
Go to: multiplicative-expression, additive-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
Go to: 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
Go to: equality-expression, ordering-expression;
Next come conjunctive expressions, left-associative.
conjunctive-expression = equality-expression
/ conjunctive-expression "&&" equality-expression
Go to: equality-expression, conjunctive-expression;
Next come disjunctive expressions, left-associative.
disjunctive-expression = conjunctive-expression
/ disjunctive-expression "||" conjunctive-expression
Go to: disjunctive-expression, conjunctive-expression;
Finally we have conditional expressions.
conditional-expression = disjunctive-expression
/ conditional-expression
"?" expression
":" conditional-expression
Go to: conditional-expression, expression, disjunctive-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
Go to: 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-definition-statement
/ conditional-statement
/ loop-statement
/ assignment-statement
/ console-statement
/ block
Go to: return-statement, variable-definition-statement, assignment-statement, console-statement, expression-statement, loop-statement, conditional-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 ";"
Go to: expression;
A return statement always takes an expression, and does not end with a semicolon.
return-statement = %s"return" expression ";"
Go to: expression;
There are two kinds of variable definition statements, which only differ in the starting keyword. The variables 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-definition-statement = ( %s"let" / %s"const" )
identifier-or-identifiers
[ ":" type ] "=" expression ";"
Go to: type, identifier-or-identifiers, expression;
identifier-or-identifiers = identifier
/ "(" identifier 1*( "," identifier ) ")"
Go to: 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
Go to: expression, block;
conditional-statement = branch
/ branch %s"else" block
/ branch %s"else" conditional-statement
Go to: branch, conditional-statement, block;
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
Go to: identifier, 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 ";"
Go to: 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
Go to: console-call;
console-call = assert-call
/ print-call
Go to: assert-call, print-call;
assert-call = %s"assert" "(" expression ")"
Go to: expression;
print-function = %s"debug" / %s"error" / %s"log"
print-arguments = "(" [ format-string *( "," expression ) ] ")"
Go to: format-string;
print-call = print-function print-arguments
Go to: 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 ) ")" ]
Go to: identifier, annotation-name;
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. Furthermore, any function may end with an 'input' parameter.
function-declaration = *annotation %s"function" identifier
"(" [ function-parameters ] ")" [ "->" type ]
block
Go to: function-parameters, block, type, identifier;
function-parameters = self-parameter
/ self-parameter "," function-inputs
/ function-inputs
Go to: self-parameter, function-inputs;
self-parameter = [ %s"mut" / %s"const" ] %s"self"
function-inputs = function-input *( "," function-input )
Go to: function-input;
function-input = [ %s"const" ] identifier ":" type
Go to: identifier, type;
input-parameter = %s"input"
A circuit member variable declaration consists of an identifier and a type. A circuit member function declaration consists of a function declaration.
member-declaration = member-variable-declaration
/ member-function-declaration
Go to: member-variable-declaration, member-function-declaration;
member-variable-declaration = identifier ":" type
Go to: identifier, type;
member-function-declaration = function-declaration
Go to: function-declaration;
A circuit declaration defines a circuit type, as consisting of member variables and functions.
circuit-declaration = *annotation %s"circuit" identifier
"{" member-declaration *( "," member-declaration ) "}"
Go to: member-declaration, identifier;
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.
import-declaration = %s"import" package-path
Go to: package-path;
package-path = "*"
/ identifier [ %s"as" identifier ]
/ package-name "." package-path
/ "(" package-path *( "," package-path ) [","] ")"
Go to: package-path, identifier, package-name;
Finally, we define a file as a sequence of zero or more declarations.
declaration = import-declaration
/ function-declaration
/ circuit-declaration
Go to: import-declaration, circuit-declaration, function-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 later 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).