//! BNF grammar: //! //! ```text //! filter = expression EOF //! expression = or //! or = and ("OR" WS+ and)* //! and = not ("AND" WS+ not)* //! not = ("NOT" WS+ not) | primary //! primary = (WS* "(" WS* expression WS* ")" WS*) | geoRadius | in | condition | exists | not_exists | to //! in = value "IN" WS* "[" value_list "]" //! condition = value ("=" | "!=" | ">" | ">=" | "<" | "<=") value //! exists = value "EXISTS" //! not_exists = value "NOT" WS+ "EXISTS" //! to = value value "TO" WS+ value //! value = WS* ( word | singleQuoted | doubleQuoted) WS+ //! value_list = (value ("," value)* ","?)? //! singleQuoted = "'" .* all but quotes "'" //! doubleQuoted = "\"" .* all but double quotes "\"" //! word = (alphanumeric | _ | - | .)+ //! geoRadius = "_geoRadius(" WS* float WS* "," WS* float WS* "," float WS* ")" //! ``` //! //! Other BNF grammar used to handle some specific errors: //! ```text //! geoPoint = WS* "_geoPoint(" (float ",")* ")" //! ``` //! //! Specific errors: //! ================ //! - If a user try to use a geoPoint, as a primary OR as a value we must throw an error. //! ```text //! field = _geoPoint(12, 13, 14) //! field < 12 AND _geoPoint(1, 2) //! ``` //! //! - If a user try to use a geoRadius as a value we must throw an error. //! ```text //! field = _geoRadius(12, 13, 14) //! ``` //! mod condition; mod error; mod value; pub use condition::{parse_condition, parse_to, Condition}; use condition::{parse_exists, parse_not_exists}; use error::{cut_with_err, ExpectedValueKind, NomErrorExt}; pub use error::{Error, ErrorKind}; use nom::branch::alt; use nom::bytes::complete::tag; use nom::character::complete::{char, multispace0}; use nom::combinator::{cut, eof, map, opt}; use nom::multi::{many0, separated_list1}; use nom::number::complete::recognize_float; use nom::sequence::{delimited, preceded, terminated, tuple}; use nom::Finish; use nom_locate::LocatedSpan; use std::fmt::Debug; use std::str::FromStr; pub(crate) use value::parse_value; use value::word_exact; pub type Span<'a> = LocatedSpan<&'a str, &'a str>; type IResult<'a, Ret> = nom::IResult, Ret, Error<'a>>; const MAX_FILTER_DEPTH: usize = 200; #[derive(Debug, Clone, Eq)] pub struct Token<'a> { /// The token in the original input, it should be used when possible. span: Span<'a>, /// If you need to modify the original input you can use the `value` field /// to store your modified input. value: Option, } impl<'a> PartialEq for Token<'a> { fn eq(&self, other: &Self) -> bool { self.span.fragment() == other.span.fragment() } } impl<'a> Token<'a> { pub fn new(span: Span<'a>, value: Option) -> Self { Self { span, value } } pub fn lexeme(&self) -> &str { &self.span } pub fn value(&self) -> &str { self.value.as_ref().map_or(&self.span, |value| value) } pub fn as_external_error(&self, error: impl std::error::Error) -> Error<'a> { Error::new_from_external(self.span, error) } pub fn parse(&self) -> Result where T: FromStr, T::Err: std::error::Error, { self.span.parse().map_err(|e| self.as_external_error(e)) } } impl<'a> From> for Token<'a> { fn from(span: Span<'a>) -> Self { Self { span, value: None } } } #[derive(Debug, Clone, PartialEq, Eq)] pub enum FilterCondition<'a> { Not(Box), Condition { fid: Token<'a>, op: Condition<'a> }, In { fid: Token<'a>, els: Vec> }, Or(Vec), And(Vec), GeoLowerThan { point: [Token<'a>; 2], radius: Token<'a> }, } impl<'a> FilterCondition<'a> { /// Returns the first token found at the specified depth, `None` if no token at this depth. pub fn token_at_depth(&self, depth: usize) -> Option<&Token> { match self { FilterCondition::Condition { fid, .. } if depth == 0 => Some(fid), FilterCondition::Or(subfilters) => { let depth = depth.saturating_sub(1); for f in subfilters.iter() { if let Some(t) = f.token_at_depth(depth) { return Some(t); } } None } FilterCondition::And(subfilters) => { let depth = depth.saturating_sub(1); for f in subfilters.iter() { if let Some(t) = f.token_at_depth(depth) { return Some(t); } } None } FilterCondition::GeoLowerThan { point: [point, _], .. } if depth == 0 => Some(point), _ => None, } } pub fn parse(input: &'a str) -> Result, Error> { if input.trim().is_empty() { return Ok(None); } let span = Span::new_extra(input, input); parse_filter(span).finish().map(|(_rem, output)| Some(output)) } } /// remove OPTIONAL whitespaces before AND after the provided parser. fn ws<'a, O>(inner: impl FnMut(Span<'a>) -> IResult) -> impl FnMut(Span<'a>) -> IResult { delimited(multispace0, inner, multispace0) } /// value_list = (value ("," value)* ","?)? fn parse_value_list<'a>(input: Span<'a>) -> IResult>> { let (input, first_value) = opt(parse_value)(input)?; if let Some(first_value) = first_value { let value_list_el_parser = preceded(ws(tag(",")), parse_value); let (input, mut values) = many0(value_list_el_parser)(input)?; let (input, _) = opt(ws(tag(",")))(input)?; values.insert(0, first_value); Ok((input, values)) } else { Ok((input, vec![])) } } /// "IN" "[" value_list "]" fn parse_in_body(input: Span) -> IResult> { let (input, _) = ws(word_exact("IN"))(input)?; // everything after `IN` can be a failure let (input, _) = cut_with_err(tag("["), |_| Error::new_from_kind(input, ErrorKind::InOpeningBracket))( input, )?; let (input, content) = cut(parse_value_list)(input)?; // everything after `IN` can be a failure let (input, _) = cut_with_err(ws(tag("]")), |_| { if eof::<_, ()>(input).is_ok() { Error::new_from_kind(input, ErrorKind::InClosingBracket) } else { let expected_value_kind = match parse_value(input) { Err(nom::Err::Error(e)) => match e.kind() { ErrorKind::ReservedKeyword(_) => ExpectedValueKind::ReservedKeyword, _ => ExpectedValueKind::Other, }, _ => ExpectedValueKind::Other, }; Error::new_from_kind(input, ErrorKind::InExpectedValue(expected_value_kind)) } })(input)?; Ok((input, content)) } /// in = value "IN" "[" value_list "]" fn parse_in(input: Span) -> IResult { let (input, value) = parse_value(input)?; let (input, content) = parse_in_body(input)?; let filter = FilterCondition::In { fid: value, els: content }; Ok((input, filter)) } /// in = value "NOT" WS* "IN" "[" value_list "]" fn parse_not_in(input: Span) -> IResult { let (input, value) = parse_value(input)?; let (input, _) = word_exact("NOT")(input)?; let (input, content) = parse_in_body(input)?; let filter = FilterCondition::Not(Box::new(FilterCondition::In { fid: value, els: content })); Ok((input, filter)) } /// or = and ("OR" and) fn parse_or(input: Span, depth: usize) -> IResult { if depth > MAX_FILTER_DEPTH { return Err(nom::Err::Error(Error::new_from_kind(input, ErrorKind::DepthLimitReached))); } let (input, first_filter) = parse_and(input, depth + 1)?; // if we found a `OR` then we MUST find something next let (input, mut ors) = many0(preceded(ws(word_exact("OR")), cut(|input| parse_and(input, depth + 1))))(input)?; let filter = if ors.is_empty() { first_filter } else { ors.insert(0, first_filter); FilterCondition::Or(ors) }; Ok((input, filter)) } /// and = not ("AND" not)* fn parse_and(input: Span, depth: usize) -> IResult { if depth > MAX_FILTER_DEPTH { return Err(nom::Err::Error(Error::new_from_kind(input, ErrorKind::DepthLimitReached))); } let (input, first_filter) = parse_not(input, depth + 1)?; // if we found a `AND` then we MUST find something next let (input, mut ands) = many0(preceded(ws(word_exact("AND")), cut(|input| parse_not(input, depth + 1))))(input)?; let filter = if ands.is_empty() { first_filter } else { ands.insert(0, first_filter); FilterCondition::And(ands) }; Ok((input, filter)) } /// not = ("NOT" WS+ not) | primary /// We can have multiple consecutive not, eg: `NOT NOT channel = mv`. /// If we parse a `NOT` we MUST parse something behind. fn parse_not(input: Span, depth: usize) -> IResult { if depth > MAX_FILTER_DEPTH { return Err(nom::Err::Error(Error::new_from_kind(input, ErrorKind::DepthLimitReached))); } alt(( map( preceded(ws(word_exact("NOT")), cut(|input| parse_not(input, depth + 1))), |e| match e { FilterCondition::Not(e) => *e, _ => FilterCondition::Not(Box::new(e)), }, ), |input| parse_primary(input, depth + 1), ))(input) } /// geoRadius = WS* "_geoRadius(float WS* "," WS* float WS* "," WS* float) /// If we parse `_geoRadius` we MUST parse the rest of the expression. fn parse_geo_radius(input: Span) -> IResult { // we want to allow space BEFORE the _geoRadius but not after let parsed = preceded( tuple((multispace0, word_exact("_geoRadius"))), // if we were able to parse `_geoRadius` and can't parse the rest of the input we return a failure cut(delimited(char('('), separated_list1(tag(","), ws(recognize_float)), char(')'))), )(input) .map_err(|e| e.map(|_| Error::new_from_kind(input, ErrorKind::Geo))); let (input, args) = parsed?; if args.len() != 3 { return Err(nom::Err::Failure(Error::new_from_kind(input, ErrorKind::Geo))); } let res = FilterCondition::GeoLowerThan { point: [args[0].into(), args[1].into()], radius: args[2].into(), }; Ok((input, res)) } /// geoPoint = WS* "_geoPoint(float WS* "," WS* float WS* "," WS* float) fn parse_geo_point(input: Span) -> IResult { // we want to forbid space BEFORE the _geoPoint but not after tuple(( multispace0, tag("_geoPoint"), // if we were able to parse `_geoPoint` we are going to return a Failure whatever happens next. cut(delimited(char('('), separated_list1(tag(","), ws(recognize_float)), char(')'))), ))(input) .map_err(|e| e.map(|_| Error::new_from_kind(input, ErrorKind::ReservedGeo("_geoPoint"))))?; // if we succeeded we still return a `Failure` because geoPoints are not allowed Err(nom::Err::Failure(Error::new_from_kind(input, ErrorKind::ReservedGeo("_geoPoint")))) } fn parse_error_reserved_keyword(input: Span) -> IResult { match parse_condition(input) { Ok(result) => Ok(result), Err(nom::Err::Error(inner) | nom::Err::Failure(inner)) => match inner.kind() { ErrorKind::ExpectedValue(ExpectedValueKind::ReservedKeyword) => { return Err(nom::Err::Failure(inner)); } _ => return Err(nom::Err::Error(inner)), }, Err(e) => { return Err(e); } } } /// primary = (WS* "(" WS* expression WS* ")" WS*) | geoRadius | condition | exists | not_exists | to fn parse_primary(input: Span, depth: usize) -> IResult { if depth > MAX_FILTER_DEPTH { return Err(nom::Err::Error(Error::new_from_kind(input, ErrorKind::DepthLimitReached))); } alt(( // if we find a first parenthesis, then we must parse an expression and find the closing parenthesis delimited( ws(char('(')), cut(|input| parse_expression(input, depth + 1)), cut_with_err(ws(char(')')), |c| { Error::new_from_kind(input, ErrorKind::MissingClosingDelimiter(c.char())) }), ), parse_geo_radius, parse_in, parse_not_in, parse_condition, parse_exists, parse_not_exists, parse_to, // the next lines are only for error handling and are written at the end to have the less possible performance impact parse_geo_point, parse_error_reserved_keyword, ))(input) // if the inner parsers did not match enough information to return an accurate error .map_err(|e| e.map_err(|_| Error::new_from_kind(input, ErrorKind::InvalidPrimary))) } /// expression = or pub fn parse_expression(input: Span, depth: usize) -> IResult { parse_or(input, depth) } /// filter = expression EOF pub fn parse_filter(input: Span) -> IResult { terminated(|input| parse_expression(input, 0), eof)(input) } #[cfg(test)] pub mod tests { use super::*; /// Create a raw [Token]. You must specify the string that appear BEFORE your element followed by your element pub fn rtok<'a>(before: &'a str, value: &'a str) -> Token<'a> { // if the string is empty we still need to return 1 for the line number let lines = before.is_empty().then(|| 1).unwrap_or_else(|| before.lines().count()); let offset = before.chars().count(); // the extra field is not checked in the tests so we can set it to nothing unsafe { Span::new_from_raw_offset(offset, lines as u32, value, "") }.into() } #[test] fn parse() { use FilterCondition as Fc; macro_rules! p { ($s:literal) => { Fc::parse($s).unwrap().unwrap() }; } // Test equal insta::assert_display_snapshot!(p!("channel = Ponce"), @"{channel} = {Ponce}"); insta::assert_display_snapshot!(p!("subscribers = 12"), @"{subscribers} = {12}"); insta::assert_display_snapshot!(p!("channel = 'Mister Mv'"), @"{channel} = {Mister Mv}"); insta::assert_display_snapshot!(p!("channel = \"Mister Mv\""), @"{channel} = {Mister Mv}"); insta::assert_display_snapshot!(p!("'dog race' = Borzoi"), @"{dog race} = {Borzoi}"); insta::assert_display_snapshot!(p!("\"dog race\" = Chusky"), @"{dog race} = {Chusky}"); insta::assert_display_snapshot!(p!("\"dog race\" = \"Bernese Mountain\""), @"{dog race} = {Bernese Mountain}"); insta::assert_display_snapshot!(p!("'dog race' = 'Bernese Mountain'"), @"{dog race} = {Bernese Mountain}"); insta::assert_display_snapshot!(p!("\"dog race\" = 'Bernese Mountain'"), @"{dog race} = {Bernese Mountain}"); // Test IN insta::assert_display_snapshot!(p!("colour IN[]"), @"{colour} IN[]"); insta::assert_display_snapshot!(p!("colour IN[green]"), @"{colour} IN[{green}, ]"); insta::assert_display_snapshot!(p!("colour IN[green,]"), @"{colour} IN[{green}, ]"); insta::assert_display_snapshot!(p!("colour NOT IN[green,blue]"), @"NOT ({colour} IN[{green}, {blue}, ])"); insta::assert_display_snapshot!(p!(" colour IN [ green , blue , ]"), @"{colour} IN[{green}, {blue}, ]"); // Test IN + OR/AND/() insta::assert_display_snapshot!(p!(" colour IN [green, blue] AND color = green "), @"AND[{colour} IN[{green}, {blue}, ], {color} = {green}, ]"); insta::assert_display_snapshot!(p!("NOT (colour IN [green, blue]) AND color = green "), @"AND[NOT ({colour} IN[{green}, {blue}, ]), {color} = {green}, ]"); insta::assert_display_snapshot!(p!("x = 1 OR NOT (colour IN [green, blue] OR color = green) "), @"OR[{x} = {1}, NOT (OR[{colour} IN[{green}, {blue}, ], {color} = {green}, ]), ]"); // Test whitespace start/end insta::assert_display_snapshot!(p!(" colour = green "), @"{colour} = {green}"); insta::assert_display_snapshot!(p!(" (colour = green OR colour = red) "), @"OR[{colour} = {green}, {colour} = {red}, ]"); insta::assert_display_snapshot!(p!(" colour IN [green, blue] AND color = green "), @"AND[{colour} IN[{green}, {blue}, ], {color} = {green}, ]"); insta::assert_display_snapshot!(p!(" colour NOT IN [green, blue] "), @"NOT ({colour} IN[{green}, {blue}, ])"); insta::assert_display_snapshot!(p!(" colour IN [green, blue] "), @"{colour} IN[{green}, {blue}, ]"); // Test conditions insta::assert_display_snapshot!(p!("channel != ponce"), @"{channel} != {ponce}"); insta::assert_display_snapshot!(p!("NOT channel = ponce"), @"NOT ({channel} = {ponce})"); insta::assert_display_snapshot!(p!("subscribers < 1000"), @"{subscribers} < {1000}"); insta::assert_display_snapshot!(p!("subscribers > 1000"), @"{subscribers} > {1000}"); insta::assert_display_snapshot!(p!("subscribers <= 1000"), @"{subscribers} <= {1000}"); insta::assert_display_snapshot!(p!("subscribers >= 1000"), @"{subscribers} >= {1000}"); insta::assert_display_snapshot!(p!("subscribers <= 1000"), @"{subscribers} <= {1000}"); insta::assert_display_snapshot!(p!("subscribers 100 TO 1000"), @"{subscribers} {100} TO {1000}"); // Test NOT + EXISTS insta::assert_display_snapshot!(p!("subscribers EXISTS"), @"{subscribers} EXISTS"); insta::assert_display_snapshot!(p!("NOT subscribers < 1000"), @"NOT ({subscribers} < {1000})"); insta::assert_display_snapshot!(p!("NOT subscribers EXISTS"), @"NOT ({subscribers} EXISTS)"); insta::assert_display_snapshot!(p!("subscribers NOT EXISTS"), @"NOT ({subscribers} EXISTS)"); insta::assert_display_snapshot!(p!("NOT subscribers NOT EXISTS"), @"{subscribers} EXISTS"); insta::assert_display_snapshot!(p!("subscribers NOT EXISTS"), @"NOT ({subscribers} EXISTS)"); insta::assert_display_snapshot!(p!("NOT subscribers 100 TO 1000"), @"NOT ({subscribers} {100} TO {1000})"); // Test nested NOT insta::assert_display_snapshot!(p!("NOT NOT NOT NOT x = 5"), @"{x} = {5}"); insta::assert_display_snapshot!(p!("NOT NOT (NOT NOT x = 5)"), @"{x} = {5}"); // Test geo radius insta::assert_display_snapshot!(p!("_geoRadius(12, 13, 14)"), @"_geoRadius({12}, {13}, {14})"); insta::assert_display_snapshot!(p!("NOT _geoRadius(12, 13, 14)"), @"NOT (_geoRadius({12}, {13}, {14}))"); // Test OR + AND insta::assert_display_snapshot!(p!("channel = ponce AND 'dog race' != 'bernese mountain'"), @"AND[{channel} = {ponce}, {dog race} != {bernese mountain}, ]"); insta::assert_display_snapshot!(p!("channel = ponce OR 'dog race' != 'bernese mountain'"), @"OR[{channel} = {ponce}, {dog race} != {bernese mountain}, ]"); insta::assert_display_snapshot!(p!("channel = ponce AND 'dog race' != 'bernese mountain' OR subscribers > 1000"), @"OR[AND[{channel} = {ponce}, {dog race} != {bernese mountain}, ], {subscribers} > {1000}, ]"); insta::assert_display_snapshot!( p!("channel = ponce AND 'dog race' != 'bernese mountain' OR subscribers > 1000 OR colour = red OR colour = blue AND size = 7"), @"OR[AND[{channel} = {ponce}, {dog race} != {bernese mountain}, ], {subscribers} > {1000}, {colour} = {red}, AND[{colour} = {blue}, {size} = {7}, ], ]" ); // Test parentheses insta::assert_display_snapshot!(p!("channel = ponce AND ( 'dog race' != 'bernese mountain' OR subscribers > 1000 )"), @"AND[{channel} = {ponce}, OR[{dog race} != {bernese mountain}, {subscribers} > {1000}, ], ]"); insta::assert_display_snapshot!(p!("(channel = ponce AND 'dog race' != 'bernese mountain' OR subscribers > 1000) AND _geoRadius(12, 13, 14)"), @"AND[OR[AND[{channel} = {ponce}, {dog race} != {bernese mountain}, ], {subscribers} > {1000}, ], _geoRadius({12}, {13}, {14}), ]"); // Test recursion // This is the most that is allowed insta::assert_display_snapshot!( p!("(((((((((((((((((((((((((((((((((((((((((((((((((x = 1)))))))))))))))))))))))))))))))))))))))))))))))))"), @"{x} = {1}" ); insta::assert_display_snapshot!( p!("NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT x = 1"), @"NOT ({x} = {1})" ); } #[test] fn error() { use FilterCondition as Fc; macro_rules! p { ($s:literal) => { Fc::parse($s).unwrap_err().to_string() }; } insta::assert_display_snapshot!(p!("channel = Ponce = 12"), @r###" Found unexpected characters at the end of the filter: `= 12`. You probably forgot an `OR` or an `AND` rule. 17:21 channel = Ponce = 12 "###); insta::assert_display_snapshot!(p!("channel = "), @r###" Was expecting a value but instead got nothing. 14:14 channel = "###); insta::assert_display_snapshot!(p!("channel = 🐻"), @r###" Was expecting a value but instead got `🐻`. 11:12 channel = 🐻 "###); insta::assert_display_snapshot!(p!("channel = 🐻 AND followers < 100"), @r###" Was expecting a value but instead got `🐻`. 11:12 channel = 🐻 AND followers < 100 "###); insta::assert_display_snapshot!(p!("'OR'"), @r###" Was expecting an operation `=`, `!=`, `>=`, `>`, `<=`, `<`, `TO`, `EXISTS`, `NOT EXISTS`, or `_geoRadius` at `\'OR\'`. 1:5 'OR' "###); insta::assert_display_snapshot!(p!("OR"), @r###" Was expecting a value but instead got `OR`, which is a reserved keyword. To use `OR` as a field name or a value, surround it by quotes. 1:3 OR "###); insta::assert_display_snapshot!(p!("channel Ponce"), @r###" Was expecting an operation `=`, `!=`, `>=`, `>`, `<=`, `<`, `TO`, `EXISTS`, `NOT EXISTS`, or `_geoRadius` at `channel Ponce`. 1:14 channel Ponce "###); insta::assert_display_snapshot!(p!("channel = Ponce OR"), @r###" Was expecting an operation `=`, `!=`, `>=`, `>`, `<=`, `<`, `TO`, `EXISTS`, `NOT EXISTS`, or `_geoRadius` but instead got nothing. 19:19 channel = Ponce OR "###); insta::assert_display_snapshot!(p!("_geoRadius"), @r###" The `_geoRadius` filter expects three arguments: `_geoRadius(latitude, longitude, radius)`. 1:11 _geoRadius "###); insta::assert_display_snapshot!(p!("_geoRadius = 12"), @r###" The `_geoRadius` filter expects three arguments: `_geoRadius(latitude, longitude, radius)`. 1:16 _geoRadius = 12 "###); insta::assert_display_snapshot!(p!("_geoPoint(12, 13, 14)"), @r###" `_geoPoint` is a reserved keyword and thus can't be used as a filter expression. Use the `_geoRadius(latitude, longitude, distance) built-in rule to filter on `_geo` coordinates. 1:22 _geoPoint(12, 13, 14) "###); insta::assert_display_snapshot!(p!("position <= _geoPoint(12, 13, 14)"), @r###" `_geoPoint` is a reserved keyword and thus can't be used as a filter expression. Use the `_geoRadius(latitude, longitude, distance) built-in rule to filter on `_geo` coordinates. 13:34 position <= _geoPoint(12, 13, 14) "###); insta::assert_display_snapshot!(p!("position <= _geoRadius(12, 13, 14)"), @r###" The `_geoRadius` filter is an operation and can't be used as a value. 13:35 position <= _geoRadius(12, 13, 14) "###); insta::assert_display_snapshot!(p!("channel = 'ponce"), @r###" Expression `\'ponce` is missing the following closing delimiter: `'`. 11:17 channel = 'ponce "###); insta::assert_display_snapshot!(p!("channel = \"ponce"), @r###" Expression `\"ponce` is missing the following closing delimiter: `"`. 11:17 channel = "ponce "###); insta::assert_display_snapshot!(p!("channel = mv OR (followers >= 1000"), @r###" Expression `(followers >= 1000` is missing the following closing delimiter: `)`. 17:35 channel = mv OR (followers >= 1000 "###); insta::assert_display_snapshot!(p!("channel = mv OR followers >= 1000)"), @r###" Found unexpected characters at the end of the filter: `)`. You probably forgot an `OR` or an `AND` rule. 34:35 channel = mv OR followers >= 1000) "###); insta::assert_display_snapshot!(p!("colour NOT EXIST"), @r###" Was expecting an operation `=`, `!=`, `>=`, `>`, `<=`, `<`, `TO`, `EXISTS`, `NOT EXISTS`, or `_geoRadius` at `colour NOT EXIST`. 1:17 colour NOT EXIST "###); insta::assert_display_snapshot!(p!("subscribers 100 TO1000"), @r###" Was expecting an operation `=`, `!=`, `>=`, `>`, `<=`, `<`, `TO`, `EXISTS`, `NOT EXISTS`, or `_geoRadius` at `subscribers 100 TO1000`. 1:23 subscribers 100 TO1000 "###); insta::assert_display_snapshot!(p!("channel = ponce ORdog != 'bernese mountain'"), @r###" Found unexpected characters at the end of the filter: `ORdog != \'bernese mountain\'`. You probably forgot an `OR` or an `AND` rule. 17:44 channel = ponce ORdog != 'bernese mountain' "###); insta::assert_display_snapshot!(p!("colour IN blue, green]"), @r###" Expected `[` after `IN` keyword. 11:23 colour IN blue, green] "###); insta::assert_display_snapshot!(p!("colour IN [blue, green, 'blue' > 2]"), @r###" Expected only comma-separated field names inside `IN[..]` but instead found `> 2]`. 32:36 colour IN [blue, green, 'blue' > 2] "###); insta::assert_display_snapshot!(p!("colour IN [blue, green, AND]"), @r###" Expected only comma-separated field names inside `IN[..]` but instead found `AND]`. 25:29 colour IN [blue, green, AND] "###); insta::assert_display_snapshot!(p!("colour IN [blue, green"), @r###" Expected matching `]` after the list of field names given to `IN[` 23:23 colour IN [blue, green "###); insta::assert_display_snapshot!(p!("colour IN ['blue, green"), @r###" Expression `\'blue, green` is missing the following closing delimiter: `'`. 12:24 colour IN ['blue, green "###); insta::assert_display_snapshot!(p!("x = EXISTS"), @r###" Was expecting a value but instead got `EXISTS`, which is a reserved keyword. To use `EXISTS` as a field name or a value, surround it by quotes. 5:11 x = EXISTS "###); insta::assert_display_snapshot!(p!("AND = 8"), @r###" Was expecting a value but instead got `AND`, which is a reserved keyword. To use `AND` as a field name or a value, surround it by quotes. 1:4 AND = 8 "###); insta::assert_display_snapshot!(p!("((((((((((((((((((((((((((((((((((((((((((((((((((x = 1))))))))))))))))))))))))))))))))))))))))))))))))))"), @r###" The filter exceeded the maximum depth limit. Try rewriting the filter so that it contains fewer nested conditions. 51:106 ((((((((((((((((((((((((((((((((((((((((((((((((((x = 1)))))))))))))))))))))))))))))))))))))))))))))))))) "###); insta::assert_display_snapshot!( p!("NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT x = 1"), @r###" The filter exceeded the maximum depth limit. Try rewriting the filter so that it contains fewer nested conditions. 797:802 NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT NOT x = 1 "### ); } #[test] fn depth() { let filter = FilterCondition::parse("account_ids=1 OR account_ids=2 OR account_ids=3 OR account_ids=4 OR account_ids=5 OR account_ids=6").unwrap().unwrap(); assert!(filter.token_at_depth(1).is_some()); assert!(filter.token_at_depth(2).is_none()); let filter = FilterCondition::parse("(account_ids=1 OR (account_ids=2 AND account_ids=3) OR (account_ids=4 AND account_ids=5) OR account_ids=6)").unwrap().unwrap(); assert!(filter.token_at_depth(2).is_some()); assert!(filter.token_at_depth(3).is_none()); let filter = FilterCondition::parse("account_ids=1 OR account_ids=2 AND account_ids=3 OR account_ids=4 AND account_ids=5 OR account_ids=6").unwrap().unwrap(); assert!(filter.token_at_depth(2).is_some()); assert!(filter.token_at_depth(3).is_none()); } } impl<'a> std::fmt::Display for FilterCondition<'a> { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { match self { FilterCondition::Not(filter) => { write!(f, "NOT ({filter})") } FilterCondition::Condition { fid, op } => { write!(f, "{fid} {op}") } FilterCondition::In { fid, els } => { write!(f, "{fid} IN[")?; for el in els { write!(f, "{el}, ")?; } write!(f, "]") } FilterCondition::Or(els) => { write!(f, "OR[")?; for el in els { write!(f, "{el}, ")?; } write!(f, "]") } FilterCondition::And(els) => { write!(f, "AND[")?; for el in els { write!(f, "{el}, ")?; } write!(f, "]") } FilterCondition::GeoLowerThan { point, radius } => { write!(f, "_geoRadius({}, {}, {})", point[0], point[1], radius) } } } } impl<'a> std::fmt::Display for Condition<'a> { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { match self { Condition::GreaterThan(token) => write!(f, "> {token}"), Condition::GreaterThanOrEqual(token) => write!(f, ">= {token}"), Condition::Equal(token) => write!(f, "= {token}"), Condition::NotEqual(token) => write!(f, "!= {token}"), Condition::Exists => write!(f, "EXISTS"), Condition::LowerThan(token) => write!(f, "< {token}"), Condition::LowerThanOrEqual(token) => write!(f, "<= {token}"), Condition::Between { from, to } => write!(f, "{from} TO {to}"), } } } impl<'a> std::fmt::Display for Token<'a> { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { write!(f, "{{{}}}", self.value()) } }