compiler/rustc_attr_parsing/src/attributes/crate_level.rs


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use std::num::IntErrorKind;

use rustc_hir::limit::Limit;

use super::prelude::*;
use crate::session_diagnostics::LimitInvalid;

impl<S: Stage> AcceptContext<'_, '_, S> {
    fn parse_limit_int(&self, nv: &NameValueParser) -> Option<Limit> {
        let Some(limit) = nv.value_as_str() else {
            self.expected_string_literal(nv.value_span, Some(nv.value_as_lit()));
            return None;
        };

        let error_str = match limit.as_str().parse() {
            Ok(i) => return Some(Limit::new(i)),
            Err(e) => match e.kind() {
                IntErrorKind::PosOverflow => "`limit` is too large",
                IntErrorKind::Empty => "`limit` must be a non-negative integer",
                IntErrorKind::InvalidDigit => "not a valid integer",
                IntErrorKind::NegOverflow => {
                    panic!(
                        "`limit` should never negatively overflow since we're parsing into a usize and we'd get Empty instead"
                    )
                }
                IntErrorKind::Zero => {
                    panic!("zero is a valid `limit` so should have returned Ok() when parsing")
                }
                kind => panic!("unimplemented IntErrorKind variant: {:?}", kind),
            },
        };

        self.emit_err(LimitInvalid { span: self.attr_span, value_span: nv.value_span, error_str });

        None
    }
}

pub(crate) struct CrateNameParser;

impl<S: Stage> SingleAttributeParser<S> for CrateNameParser {
    const PATH: &[Symbol] = &[sym::crate_name];
    const ATTRIBUTE_ORDER: AttributeOrder = AttributeOrder::KeepOutermost;
    const ON_DUPLICATE: OnDuplicate<S> = OnDuplicate::WarnButFutureError;
    const TEMPLATE: AttributeTemplate = template!(NameValueStr: "name");
    const ALLOWED_TARGETS: AllowedTargets = AllowedTargets::CrateLevel;

    fn convert(cx: &mut AcceptContext<'_, '_, S>, args: &ArgParser<'_>) -> Option<AttributeKind> {
        let ArgParser::NameValue(n) = args else {
            cx.expected_name_value(cx.attr_span, None);
            return None;
        };

        let Some(name) = n.value_as_str() else {
            cx.expected_string_literal(n.value_span, Some(n.value_as_lit()));
            return None;
        };

        Some(AttributeKind::CrateName {
            name,
            name_span: n.value_span,
            attr_span: cx.attr_span,
            style: cx.attr_style,
        })
    }
}

pub(crate) struct RecursionLimitParser;

impl<S: Stage> SingleAttributeParser<S> for RecursionLimitParser {
    const PATH: &[Symbol] = &[sym::recursion_limit];
    const ATTRIBUTE_ORDER: AttributeOrder = AttributeOrder::KeepOutermost;
    const ON_DUPLICATE: OnDuplicate<S> = OnDuplicate::WarnButFutureError;
    const TEMPLATE: AttributeTemplate = template!(NameValueStr: "N", "https://doc.rust-lang.org/reference/attributes/limits.html#the-recursion_limit-attribute");
    const ALLOWED_TARGETS: AllowedTargets = AllowedTargets::CrateLevel;

    fn convert(cx: &mut AcceptContext<'_, '_, S>, args: &ArgParser<'_>) -> Option<AttributeKind> {
        let ArgParser::NameValue(nv) = args else {
            cx.expected_name_value(cx.attr_span, None);
            return None;
        };

        Some(AttributeKind::RecursionLimit {
            limit: cx.parse_limit_int(nv)?,
            attr_span: cx.attr_span,
            limit_span: nv.value_span,
        })
    }
}

pub(crate) struct MoveSizeLimitParser;

impl<S: Stage> SingleAttributeParser<S> for MoveSizeLimitParser {
    const PATH: &[Symbol] = &[sym::move_size_limit];
    const ATTRIBUTE_ORDER: AttributeOrder = AttributeOrder::KeepOutermost;
    const ON_DUPLICATE: OnDuplicate<S> = OnDuplicate::Error;
    const TEMPLATE: AttributeTemplate = template!(NameValueStr: "N");
    const ALLOWED_TARGETS: AllowedTargets = AllowedTargets::CrateLevel;

    fn convert(cx: &mut AcceptContext<'_, '_, S>, args: &ArgParser<'_>) -> Option<AttributeKind> {
        let ArgParser::NameValue(nv) = args else {
            cx.expected_name_value(cx.attr_span, None);
            return None;
        };

        Some(AttributeKind::MoveSizeLimit {
            limit: cx.parse_limit_int(nv)?,
            attr_span: cx.attr_span,
            limit_span: nv.value_span,
        })
    }
}

pub(crate) struct TypeLengthLimitParser;

impl<S: Stage> SingleAttributeParser<S> for TypeLengthLimitParser {
    const PATH: &[Symbol] = &[sym::type_length_limit];
    const ATTRIBUTE_ORDER: AttributeOrder = AttributeOrder::KeepOutermost;
    const ON_DUPLICATE: OnDuplicate<S> = OnDuplicate::WarnButFutureError;
    const TEMPLATE: AttributeTemplate = template!(NameValueStr: "N");
    const ALLOWED_TARGETS: AllowedTargets = AllowedTargets::CrateLevel;

    fn convert(cx: &mut AcceptContext<'_, '_, S>, args: &ArgParser<'_>) -> Option<AttributeKind> {
        let ArgParser::NameValue(nv) = args else {
            cx.expected_name_value(cx.attr_span, None);
            return None;
        };

        Some(AttributeKind::TypeLengthLimit {
            limit: cx.parse_limit_int(nv)?,
            attr_span: cx.attr_span,
            limit_span: nv.value_span,
        })
    }
}

pub(crate) struct PatternComplexityLimitParser;

impl<S: Stage> SingleAttributeParser<S> for PatternComplexityLimitParser {
    const PATH: &[Symbol] = &[sym::pattern_complexity_limit];
    const ATTRIBUTE_ORDER: AttributeOrder = AttributeOrder::KeepOutermost;
    const ON_DUPLICATE: OnDuplicate<S> = OnDuplicate::Error;
    const TEMPLATE: AttributeTemplate = template!(NameValueStr: "N");
    const ALLOWED_TARGETS: AllowedTargets = AllowedTargets::CrateLevel;

    fn convert(cx: &mut AcceptContext<'_, '_, S>, args: &ArgParser<'_>) -> Option<AttributeKind> {
        let ArgParser::NameValue(nv) = args else {
            cx.expected_name_value(cx.attr_span, None);
            return None;
        };

        Some(AttributeKind::PatternComplexityLimit {
            limit: cx.parse_limit_int(nv)?,
            attr_span: cx.attr_span,
            limit_span: nv.value_span,
        })
    }
}

pub(crate) struct NoCoreParser;

impl<S: Stage> NoArgsAttributeParser<S> for NoCoreParser {
    const PATH: &[Symbol] = &[sym::no_core];
    const ON_DUPLICATE: OnDuplicate<S> = OnDuplicate::Warn;
    const ALLOWED_TARGETS: AllowedTargets = AllowedTargets::CrateLevel;
    const CREATE: fn(Span) -> AttributeKind = AttributeKind::NoCore;
}

pub(crate) struct NoStdParser;

impl<S: Stage> NoArgsAttributeParser<S> for NoStdParser {
    const PATH: &[Symbol] = &[sym::no_std];
    const ON_DUPLICATE: OnDuplicate<S> = OnDuplicate::Warn;
    const ALLOWED_TARGETS: AllowedTargets = AllowedTargets::CrateLevel;
    const CREATE: fn(Span) -> AttributeKind = AttributeKind::NoStd;
}

pub(crate) struct RustcCoherenceIsCoreParser;

impl<S: Stage> NoArgsAttributeParser<S> for RustcCoherenceIsCoreParser {
    const PATH: &[Symbol] = &[sym::rustc_coherence_is_core];
    const ON_DUPLICATE: OnDuplicate<S> = OnDuplicate::Error;
    const ALLOWED_TARGETS: AllowedTargets = AllowedTargets::CrateLevel;
    const CREATE: fn(Span) -> AttributeKind = AttributeKind::RustcCoherenceIsCore;
}