parser.rs - mozsearch

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/*!

Parsing flags from text.

Format and parse a flags value as text using the following grammar:

- _Flags:_ (_Whitespace_ _Flag_ _Whitespace_)`|`*

- _Flag:_ _Name_ | _Hex Number_

- _Name:_ The name of any defined flag

- _Hex Number_: `0x`([0-9a-fA-F])*

- _Whitespace_: (\s)*

As an example, this is how `Flags::A | Flags::B | 0x0c` can be represented as text:

```text

A | B | 0x0c

```

Alternatively, it could be represented without whitespace:

```text

A|B|0x0C

```

Note that identifiers are *case-sensitive*, so the following is *not equivalent*:

```text

a|b|0x0C

```

*/

#![allow(clippy::let_unit_value)]

use core::fmt::{self, Write};

use crate::{Bits, Flags};

/**

Write a flags value as text.

Any bits that aren't part of a contained flag will be formatted as a hex number.

*/

pub fn to_writer<B: Flags>(flags: &B, mut writer: impl Write) -> Result<(), fmt::Error>

where

    B::Bits: WriteHex,

    // A formatter for bitflags that produces text output like:

//

    // A | B | 0xf6

//

    // The names of set flags are written in a bar-separated-format,

    // followed by a hex number of any remaining bits that are set

    // but don't correspond to any flags.

    // Iterate over known flag values

    let mut first = true;

    let mut iter = flags.iter_names();

    for (name, _) in &mut iter {

        if !first {

            writer.write_str(" | ")?;

        first = false;

        writer.write_str(name)?;

    // Append any extra bits that correspond to flags to the end of the format

    let remaining = iter.remaining().bits();

    if remaining != B::Bits::EMPTY {

        if !first {

            writer.write_str(" | ")?;

        writer.write_str("0x")?;

        remaining.write_hex(writer)?;

    fmt::Result::Ok(())

#[cfg(feature = "serde")]

pub(crate) struct AsDisplay<'a, B>(pub(crate) &'a B);

#[cfg(feature = "serde")]

impl<'a, B: Flags> fmt::Display for AsDisplay<'a, B>

where

    B::Bits: WriteHex,

    fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {

        to_writer(self.0, f)

/**

Parse a flags value from text.

This function will fail on any names that don't correspond to defined flags.

Unknown bits will be retained.

*/

pub fn from_str<B: Flags>(input: &str) -> Result<B, ParseError>

where

    B::Bits: ParseHex,

    let mut parsed_flags = B::empty();

    // If the input is empty then return an empty set of flags

    if input.trim().is_empty() {

        return Ok(parsed_flags);

    for flag in input.split('|') {

        let flag = flag.trim();

        // If the flag is empty then we've got missing input

        if flag.is_empty() {

            return Err(ParseError::empty_flag());

        // If the flag starts with `0x` then it's a hex number

        // Parse it directly to the underlying bits type

        let parsed_flag = if let Some(flag) = flag.strip_prefix("0x") {

            let bits =

                <B::Bits>::parse_hex(flag).map_err(|_| ParseError::invalid_hex_flag(flag))?;

            B::from_bits_retain(bits)

        // Otherwise the flag is a name

        // The generated flags type will determine whether

        // or not it's a valid identifier

        else {

            B::from_name(flag).ok_or_else(|| ParseError::invalid_named_flag(flag))?

};

        parsed_flags.insert(parsed_flag);

    Ok(parsed_flags)

/**

Write a flags value as text, ignoring any unknown bits.

*/

pub fn to_writer_truncate<B: Flags>(flags: &B, writer: impl Write) -> Result<(), fmt::Error>

where

    B::Bits: WriteHex,

    to_writer(&B::from_bits_truncate(flags.bits()), writer)

/**

Parse a flags value from text.

This function will fail on any names that don't correspond to defined flags.

Unknown bits will be ignored.

*/

pub fn from_str_truncate<B: Flags>(input: &str) -> Result<B, ParseError>

where

    B::Bits: ParseHex,

    Ok(B::from_bits_truncate(from_str::<B>(input)?.bits()))

/**

Write only the contained, defined, named flags in a flags value as text.

*/

pub fn to_writer_strict<B: Flags>(flags: &B, mut writer: impl Write) -> Result<(), fmt::Error> {

    // This is a simplified version of `to_writer` that ignores

    // any bits not corresponding to a named flag

    let mut first = true;

    let mut iter = flags.iter_names();

    for (name, _) in &mut iter {

        if !first {

            writer.write_str(" | ")?;

        first = false;

        writer.write_str(name)?;

    fmt::Result::Ok(())

/**

Parse a flags value from text.

This function will fail on any names that don't correspond to defined flags.

This function will fail to parse hex values.

*/

pub fn from_str_strict<B: Flags>(input: &str) -> Result<B, ParseError> {

    // This is a simplified version of `from_str` that ignores

    // any bits not corresponding to a named flag

    let mut parsed_flags = B::empty();

    // If the input is empty then return an empty set of flags

    if input.trim().is_empty() {

        return Ok(parsed_flags);

    for flag in input.split('|') {

        let flag = flag.trim();

        // If the flag is empty then we've got missing input

        if flag.is_empty() {

            return Err(ParseError::empty_flag());

        // If the flag starts with `0x` then it's a hex number

        // These aren't supported in the strict parser

        if flag.starts_with("0x") {

            return Err(ParseError::invalid_hex_flag("unsupported hex flag value"));

        let parsed_flag = B::from_name(flag).ok_or_else(|| ParseError::invalid_named_flag(flag))?;

        parsed_flags.insert(parsed_flag);

    Ok(parsed_flags)

/**

Encode a value as a hex string.

Implementors of this trait should not write the `0x` prefix.

*/

pub trait WriteHex {

    /// Write the value as hex.

    fn write_hex<W: fmt::Write>(&self, writer: W) -> fmt::Result;

/**

Parse a value from a hex string.

*/

pub trait ParseHex {

    /// Parse the value from hex.

    fn parse_hex(input: &str) -> Result<Self, ParseError>

    where

        Self: Sized;

/// An error encountered while parsing flags from text.

#[derive(Debug)]

pub struct ParseError(ParseErrorKind);

#[derive(Debug)]

#[allow(clippy::enum_variant_names)]

enum ParseErrorKind {

    EmptyFlag,

    InvalidNamedFlag {

        #[cfg(not(feature = "std"))]

        got: (),

        #[cfg(feature = "std")]

        got: String,

},

    InvalidHexFlag {

        #[cfg(not(feature = "std"))]

        got: (),

        #[cfg(feature = "std")]

        got: String,

},

impl ParseError {

    /// An invalid hex flag was encountered.

    pub fn invalid_hex_flag(flag: impl fmt::Display) -> Self {

        let _flag = flag;

        let got = {

            #[cfg(feature = "std")]

                _flag.to_string()

};

        ParseError(ParseErrorKind::InvalidHexFlag { got })

    /// A named flag that doesn't correspond to any on the flags type was encountered.

    pub fn invalid_named_flag(flag: impl fmt::Display) -> Self {

        let _flag = flag;

        let got = {

            #[cfg(feature = "std")]

                _flag.to_string()

};

        ParseError(ParseErrorKind::InvalidNamedFlag { got })

    /// A hex or named flag wasn't found between separators.

    pub const fn empty_flag() -> Self {

        ParseError(ParseErrorKind::EmptyFlag)

impl fmt::Display for ParseError {

    fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {

        match &self.0 {

            ParseErrorKind::InvalidNamedFlag { got } => {

                let _got = got;

                write!(f, "unrecognized named flag")?;

                #[cfg(feature = "std")]

                    write!(f, " `{}`", _got)?;

            ParseErrorKind::InvalidHexFlag { got } => {

                let _got = got;

                write!(f, "invalid hex flag")?;

                #[cfg(feature = "std")]

                    write!(f, " `{}`", _got)?;

            ParseErrorKind::EmptyFlag => {

                write!(f, "encountered empty flag")?;

        Ok(())

#[cfg(feature = "std")]

impl std::error::Error for ParseError {}