rust-clippy/src/cyclomatic_complexity.rs

//! calculate cyclomatic complexity and warn about overly complex functions

use rustc::lint::*;
use rustc::cfg::CFG;
use rustc::ty;
use rustc_front::hir::*;
use rustc_front::intravisit::{Visitor, walk_expr};
use syntax::ast::Attribute;
use syntax::attr::*;
use syntax::codemap::Span;

use utils::{in_macro, LimitStack, span_help_and_lint};

/// **What it does:** This lint checks for methods with high cyclomatic complexity
///
/// **Why is this bad?** Methods of high cyclomatic complexity tend to be badly readable. Also LLVM will usually optimize small methods better.
///
/// **Known problems:** Sometimes it's hard to find a way to reduce the complexity
///
/// **Example:** No. You'll see it when you get the warning.
declare_lint! {
    pub CYCLOMATIC_COMPLEXITY, Warn,
    "finds functions that should be split up into multiple functions"
}

pub struct CyclomaticComplexity {
    limit: LimitStack,
}

impl CyclomaticComplexity {
    pub fn new(limit: u64) -> Self {
        CyclomaticComplexity { limit: LimitStack::new(limit) }
    }
}

impl LintPass for CyclomaticComplexity {
    fn get_lints(&self) -> LintArray {
        lint_array!(CYCLOMATIC_COMPLEXITY)
    }
}

impl CyclomaticComplexity {
    fn check<'a, 'tcx>(&mut self, cx: &'a LateContext<'a, 'tcx>, block: &Block, span: Span) {
        if in_macro(cx, span) {
            return;
        }
        let cfg = CFG::new(cx.tcx, block);
        let n = cfg.graph.len_nodes() as u64;
        let e = cfg.graph.len_edges() as u64;
        if e + 2 < n {
            // the function has unreachable code, other lints should catch this
            return;
        }
        let cc = e + 2 - n;
        let mut helper = CCHelper {
            match_arms: 0,
            divergence: 0,
            short_circuits: 0,
            tcx: &cx.tcx,
        };
        helper.visit_block(block);
        let CCHelper {
            match_arms,
            divergence,
            short_circuits,
            ..
        } = helper;

        if cc + divergence < match_arms + short_circuits {
            report_cc_bug(cx, cc, match_arms, divergence, short_circuits, span);
        } else {
            let rust_cc = cc + divergence - match_arms - short_circuits;
            if rust_cc > self.limit.limit() {
                span_help_and_lint(cx,
                                   CYCLOMATIC_COMPLEXITY,
                                   span,
                                   &format!("the function has a cyclomatic complexity of {}", rust_cc),
                                   "you could split it up into multiple smaller functions");
            }
        }
    }
}

impl LateLintPass for CyclomaticComplexity {
    fn check_item(&mut self, cx: &LateContext, item: &Item) {
        if let ItemFn(_, _, _, _, _, ref block) = item.node {
            self.check(cx, block, item.span);
        }
    }

    fn check_impl_item(&mut self, cx: &LateContext, item: &ImplItem) {
        if let ImplItemKind::Method(_, ref block) = item.node {
            self.check(cx, block, item.span);
        }
    }

    fn check_trait_item(&mut self, cx: &LateContext, item: &TraitItem) {
        if let MethodTraitItem(_, Some(ref block)) = item.node {
            self.check(cx, block, item.span);
        }
    }

    fn enter_lint_attrs(&mut self, cx: &LateContext, attrs: &[Attribute]) {
        self.limit.push_attrs(cx.sess(), attrs, "cyclomatic_complexity");
    }
    fn exit_lint_attrs(&mut self, cx: &LateContext, attrs: &[Attribute]) {
        self.limit.pop_attrs(cx.sess(), attrs, "cyclomatic_complexity");
    }
}

struct CCHelper<'a, 'tcx: 'a> {
    match_arms: u64,
    divergence: u64,
    short_circuits: u64, // && and ||
    tcx: &'a ty::TyCtxt<'tcx>,
}

impl<'a, 'b, 'tcx> Visitor<'a> for CCHelper<'b, 'tcx> {
    fn visit_expr(&mut self, e: &'a Expr) {
        match e.node {
            ExprMatch(_, ref arms, _) => {
                walk_expr(self, e);
                let arms_n: u64 = arms.iter().map(|arm| arm.pats.len() as u64).sum();
                if arms_n > 1 {
                    self.match_arms += arms_n - 2;
                }
            }
            ExprCall(ref callee, _) => {
                walk_expr(self, e);
                let ty = self.tcx.node_id_to_type(callee.id);
                match ty.sty {
                    ty::TyFnDef(_, _, ty) | ty::TyFnPtr(ty) if ty.sig.skip_binder().output.diverges() => {
                        self.divergence += 1;
                    }
                    _ => (),
                }
            }
            ExprClosure(..) => (),
            ExprBinary(op, _, _) => {
                walk_expr(self, e);
                match op.node {
                    BiAnd | BiOr => self.short_circuits += 1,
                    _ => {},
                }
            }
            _ => walk_expr(self, e),
        }
    }
}

#[cfg(feature="debugging")]
fn report_cc_bug(cx: &LateContext, cc: u64, narms: u64, div: u64, shorts: u64, span: Span) {
    cx.sess().span_bug(span,
                       &format!("Clippy encountered a bug calculating cyclomatic complexity: cc = {}, arms = {}, \
                                 div = {}, shorts = {}. Please file a bug report.",
                                cc,
                                narms,
                                div,
                                shorts));;
}
#[cfg(not(feature="debugging"))]
fn report_cc_bug(cx: &LateContext, cc: u64, narms: u64, div: u64, shorts: u64, span: Span) {
    if cx.current_level(CYCLOMATIC_COMPLEXITY) != Level::Allow {
        cx.sess().span_note_without_error(span,
                                          &format!("Clippy encountered a bug calculating cyclomatic complexity \
                                                    (hide this message with `#[allow(cyclomatic_complexity)]`): cc \
                                                    = {}, arms = {}, div = {}, shorts = {}. Please file a bug report.",
                                                   cc,
                                                   narms,
                                                   div,
                                                   shorts));
    }
}
compute cyclomatic complexity (adjusted to not punish Rust's `match`) 2015-11-18 11:35:18 +00:00			`//! calculate cyclomatic complexity and warn about overly complex functions`

			`use rustc::lint::*;`
Update rust-clippy to rustc 1.9.0-nightly (d5a91e695 2016-03-26) move cfg, infer, traits and ty from middle to top-level move middle::subst into middle::ty track the extern-crate def-id rather than path (rustc ab9b844) 2016-03-27 18:59:02 +00:00			`use rustc::cfg::CFG;`
			`use rustc::ty;`
Rustfmt and sort all `use` items 2016-02-24 16:38:57 +00:00			`use rustc_front::hir::*;`
compute cyclomatic complexity (adjusted to not punish Rust's `match`) 2015-11-18 11:35:18 +00:00			`use rustc_front::intravisit::{Visitor, walk_expr};`
Rustfmt and sort all `use` items 2016-02-24 16:38:57 +00:00			`use syntax::ast::Attribute;`
			`use syntax::attr::*;`
			`use syntax::codemap::Span;`
compute cyclomatic complexity (adjusted to not punish Rust's `match`) 2015-11-18 11:35:18 +00:00
Rustup to syntax::errors changes 2015-12-31 20:39:03 +00:00			`use utils::{in_macro, LimitStack, span_help_and_lint};`
compute cyclomatic complexity (adjusted to not punish Rust's `match`) 2015-11-18 11:35:18 +00:00
Remove redundancy in lint documentation The default level is always given in the declare_lint! macro, no need to add it inconsistently in the documentation. 2016-02-05 23:41:54 +00:00			`/// What it does: This lint checks for methods with high cyclomatic complexity`
adding missing doc comments 2015-12-14 21:16:56 +00:00			`///`
			`/// Why is this bad? Methods of high cyclomatic complexity tend to be badly readable. Also LLVM will usually optimize small methods better.`
			`///`
			`/// Known problems: Sometimes it's hard to find a way to reduce the complexity`
			`///`
			`/// Example: No. You'll see it when you get the warning.`
Fix util/update_wiki.py warnings and be consistent in declare_lint! invocations 2016-02-05 23:13:29 +00:00			`declare_lint! {`
			`pub CYCLOMATIC_COMPLEXITY, Warn,`
			`"finds functions that should be split up into multiple functions"`
			`}`
compute cyclomatic complexity (adjusted to not punish Rust's `match`) 2015-11-18 11:35:18 +00:00
			`pub struct CyclomaticComplexity {`
			`limit: LimitStack,`
			`}`

			`impl CyclomaticComplexity {`
			`pub fn new(limit: u64) -> Self {`
fmt clippy 2016-01-04 04:26:12 +00:00			`CyclomaticComplexity { limit: LimitStack::new(limit) }`
compute cyclomatic complexity (adjusted to not punish Rust's `match`) 2015-11-18 11:35:18 +00:00			`}`
			`}`

			`impl LintPass for CyclomaticComplexity {`
			`fn get_lints(&self) -> LintArray {`
			`lint_array!(CYCLOMATIC_COMPLEXITY)`
			`}`
			`}`

			`impl CyclomaticComplexity {`
fix cc computation in the presence of diverging calls CFG treats diverging calls as its completely own path out of the function. While this makes sense, it should also mean that a panic should increase the cyclomatic complexity. Instead it decreases it. Minimal example: ```rust if a { b } else { panic!("cake"); } d ``` creates the following graph ```dot digraph G { "if a" -> "b" "if a" -> "panic!(\"cake\")" "b" -> c } ``` which has a CC of 1 (3 - 4 + 2). A CC of 1 means there is one path through the program. Obviously that is wrong. There are two paths. One returning normally, and one panicking. 2015-12-14 13:29:20 +00:00			`fn check<'a, 'tcx>(&mut self, cx: &'a LateContext<'a, 'tcx>, block: &Block, span: Span) {`
fmt clippy 2016-01-04 04:26:12 +00:00			`if in_macro(cx, span) {`
			`return;`
			`}`
compute cyclomatic complexity (adjusted to not punish Rust's `match`) 2015-11-18 11:35:18 +00:00			`let cfg = CFG::new(cx.tcx, block);`
			`let n = cfg.graph.len_nodes() as u64;`
			`let e = cfg.graph.len_edges() as u64;`
prevent cc lint from panicking on unreachable code 2016-03-14 16:24:55 +00:00			`if e + 2 < n {`
			`// the function has unreachable code, other lints should catch this`
			`return;`
			`}`
compute cyclomatic complexity (adjusted to not punish Rust's `match`) 2015-11-18 11:35:18 +00:00			`let cc = e + 2 - n;`
simplify cyclomatic complexity auxiliarly value computation previously the HIR was unnecessarily traversed twice 2016-03-04 15:27:03 +00:00			`let mut helper = CCHelper {`
			`match_arms: 0,`
			`divergence: 0,`
fix cyclomatic complexity lint triggering because of short circuit operations 2016-03-08 14:10:02 +00:00			`short_circuits: 0,`
simplify cyclomatic complexity auxiliarly value computation previously the HIR was unnecessarily traversed twice 2016-03-04 15:27:03 +00:00			`tcx: &cx.tcx,`
			`};`
			`helper.visit_block(block);`
			`let CCHelper {`
			`match_arms,`
			`divergence,`
fix cyclomatic complexity lint triggering because of short circuit operations 2016-03-08 14:10:02 +00:00			`short_circuits,`
simplify cyclomatic complexity auxiliarly value computation previously the HIR was unnecessarily traversed twice 2016-03-04 15:27:03 +00:00			`..`
			`} = helper;`

fix cyclomatic complexity lint triggering because of short circuit operations 2016-03-08 14:10:02 +00:00			`if cc + divergence < match_arms + short_circuits {`
			`report_cc_bug(cx, cc, match_arms, divergence, short_circuits, span);`
Make panic in CC silencable (partial #478) 2015-12-05 08:53:00 +00:00			`} else {`
fix cyclomatic complexity lint triggering because of short circuit operations 2016-03-08 14:10:02 +00:00			`let rust_cc = cc + divergence - match_arms - short_circuits;`
Make panic in CC silencable (partial #478) 2015-12-05 08:53:00 +00:00			`if rust_cc > self.limit.limit() {`
fmt clippy 2016-01-04 04:26:12 +00:00			`span_help_and_lint(cx,`
			`CYCLOMATIC_COMPLEXITY,`
			`span,`
Fix case conventions 2016-02-05 20:54:29 +00:00			`&format!("the function has a cyclomatic complexity of {}", rust_cc),`
			`"you could split it up into multiple smaller functions");`
Make panic in CC silencable (partial #478) 2015-12-05 08:53:00 +00:00			`}`
compute cyclomatic complexity (adjusted to not punish Rust's `match`) 2015-11-18 11:35:18 +00:00			`}`
			`}`
			`}`

			`impl LateLintPass for CyclomaticComplexity {`
			`fn check_item(&mut self, cx: &LateContext, item: &Item) {`
			`if let ItemFn(_, _, _, _, _, ref block) = item.node {`
			`self.check(cx, block, item.span);`
			`}`
			`}`

			`fn check_impl_item(&mut self, cx: &LateContext, item: &ImplItem) {`
			`if let ImplItemKind::Method(_, ref block) = item.node {`
			`self.check(cx, block, item.span);`
			`}`
			`}`

			`fn check_trait_item(&mut self, cx: &LateContext, item: &TraitItem) {`
			`if let MethodTraitItem(_, Some(ref block)) = item.node {`
			`self.check(cx, block, item.span);`
			`}`
			`}`

			`fn enter_lint_attrs(&mut self, cx: &LateContext, attrs: &[Attribute]) {`
			`self.limit.push_attrs(cx.sess(), attrs, "cyclomatic_complexity");`
			`}`
			`fn exit_lint_attrs(&mut self, cx: &LateContext, attrs: &[Attribute]) {`
			`self.limit.pop_attrs(cx.sess(), attrs, "cyclomatic_complexity");`
			`}`
			`}`

simplify cyclomatic complexity auxiliarly value computation previously the HIR was unnecessarily traversed twice 2016-03-04 15:27:03 +00:00			`struct CCHelper<'a, 'tcx: 'a> {`
			`match_arms: u64,`
			`divergence: u64,`
fix cyclomatic complexity lint triggering because of short circuit operations 2016-03-08 14:10:02 +00:00			`short_circuits: u64, // && and \|\|`
simplify cyclomatic complexity auxiliarly value computation previously the HIR was unnecessarily traversed twice 2016-03-04 15:27:03 +00:00			`tcx: &'a ty::TyCtxt<'tcx>,`
			`}`
compute cyclomatic complexity (adjusted to not punish Rust's `match`) 2015-11-18 11:35:18 +00:00
simplify cyclomatic complexity auxiliarly value computation previously the HIR was unnecessarily traversed twice 2016-03-04 15:27:03 +00:00			`impl<'a, 'b, 'tcx> Visitor<'a> for CCHelper<'b, 'tcx> {`
compute cyclomatic complexity (adjusted to not punish Rust's `match`) 2015-11-18 11:35:18 +00:00			`fn visit_expr(&mut self, e: &'a Expr) {`
			`match e.node {`
			`ExprMatch(_, ref arms, _) => {`
			`walk_expr(self, e);`
			`let arms_n: u64 = arms.iter().map(\|arm\| arm.pats.len() as u64).sum();`
fix cc computation in the presence of diverging calls CFG treats diverging calls as its completely own path out of the function. While this makes sense, it should also mean that a panic should increase the cyclomatic complexity. Instead it decreases it. Minimal example: ```rust if a { b } else { panic!("cake"); } d ``` creates the following graph ```dot digraph G { "if a" -> "b" "if a" -> "panic!(\"cake\")" "b" -> c } ``` which has a CC of 1 (3 - 4 + 2). A CC of 1 means there is one path through the program. Obviously that is wrong. There are two paths. One returning normally, and one panicking. 2015-12-14 13:29:20 +00:00			`if arms_n > 1 {`
simplify cyclomatic complexity auxiliarly value computation previously the HIR was unnecessarily traversed twice 2016-03-04 15:27:03 +00:00			`self.match_arms += arms_n - 2;`
fix cc computation in the presence of diverging calls CFG treats diverging calls as its completely own path out of the function. While this makes sense, it should also mean that a panic should increase the cyclomatic complexity. Instead it decreases it. Minimal example: ```rust if a { b } else { panic!("cake"); } d ``` creates the following graph ```dot digraph G { "if a" -> "b" "if a" -> "panic!(\"cake\")" "b" -> c } ``` which has a CC of 1 (3 - 4 + 2). A CC of 1 means there is one path through the program. Obviously that is wrong. There are two paths. One returning normally, and one panicking. 2015-12-14 13:29:20 +00:00			`}`
fmt clippy 2016-01-04 04:26:12 +00:00			`}`
fix cc computation in the presence of diverging calls CFG treats diverging calls as its completely own path out of the function. While this makes sense, it should also mean that a panic should increase the cyclomatic complexity. Instead it decreases it. Minimal example: ```rust if a { b } else { panic!("cake"); } d ``` creates the following graph ```dot digraph G { "if a" -> "b" "if a" -> "panic!(\"cake\")" "b" -> c } ``` which has a CC of 1 (3 - 4 + 2). A CC of 1 means there is one path through the program. Obviously that is wrong. There are two paths. One returning normally, and one panicking. 2015-12-14 13:29:20 +00:00			`ExprCall(ref callee, _) => {`
			`walk_expr(self, e);`
simplify cyclomatic complexity auxiliarly value computation previously the HIR was unnecessarily traversed twice 2016-03-04 15:27:03 +00:00			`let ty = self.tcx.node_id_to_type(callee.id);`
Rustup to 1.9.0-nightly (c9629d61c 2016-03-10) 2016-03-10 17:13:49 +00:00			`match ty.sty {`
			`ty::TyFnDef(_, _, ty) \| ty::TyFnPtr(ty) if ty.sig.skip_binder().output.diverges() => {`
simplify cyclomatic complexity auxiliarly value computation previously the HIR was unnecessarily traversed twice 2016-03-04 15:27:03 +00:00			`self.divergence += 1;`
fix cc computation in the presence of diverging calls CFG treats diverging calls as its completely own path out of the function. While this makes sense, it should also mean that a panic should increase the cyclomatic complexity. Instead it decreases it. Minimal example: ```rust if a { b } else { panic!("cake"); } d ``` creates the following graph ```dot digraph G { "if a" -> "b" "if a" -> "panic!(\"cake\")" "b" -> c } ``` which has a CC of 1 (3 - 4 + 2). A CC of 1 means there is one path through the program. Obviously that is wrong. There are two paths. One returning normally, and one panicking. 2015-12-14 13:29:20 +00:00			`}`
Rustup to 1.9.0-nightly (c9629d61c 2016-03-10) 2016-03-10 17:13:49 +00:00			`_ => (),`
compute cyclomatic complexity (adjusted to not punish Rust's `match`) 2015-11-18 11:35:18 +00:00			`}`
fmt clippy 2016-01-04 04:26:12 +00:00			`}`
Rustup to 1.9.0-nightly (c9629d61c 2016-03-10) 2016-03-10 17:13:49 +00:00			`ExprClosure(..) => (),`
fix cyclomatic complexity lint triggering because of short circuit operations 2016-03-08 14:10:02 +00:00			`ExprBinary(op, _, _) => {`
			`walk_expr(self, e);`
			`match op.node {`
			`BiAnd \| BiOr => self.short_circuits += 1,`
			`_ => {},`
			`}`
			`}`
compute cyclomatic complexity (adjusted to not punish Rust's `match`) 2015-11-18 11:35:18 +00:00			`_ => walk_expr(self, e),`
			`}`
			`}`
			`}`
Make panic in CC silencable (partial #478) 2015-12-05 08:53:00 +00:00
			`#[cfg(feature="debugging")]`
fix cyclomatic complexity lint triggering because of short circuit operations 2016-03-08 14:10:02 +00:00			`fn report_cc_bug(cx: &LateContext, cc: u64, narms: u64, div: u64, shorts: u64, span: Span) {`
fmt clippy 2016-01-04 04:26:12 +00:00			`cx.sess().span_bug(span,`
			`&format!("Clippy encountered a bug calculating cyclomatic complexity: cc = {}, arms = {}, \`
fix cyclomatic complexity lint triggering because of short circuit operations 2016-03-08 14:10:02 +00:00			`div = {}, shorts = {}. Please file a bug report.",`
fmt clippy 2016-01-04 04:26:12 +00:00			`cc,`
			`narms,`
fix cyclomatic complexity lint triggering because of short circuit operations 2016-03-08 14:10:02 +00:00			`div,`
			`shorts));;`
Make panic in CC silencable (partial #478) 2015-12-05 08:53:00 +00:00			`}`
			`#[cfg(not(feature="debugging"))]`
fix cyclomatic complexity lint triggering because of short circuit operations 2016-03-08 14:10:02 +00:00			`fn report_cc_bug(cx: &LateContext, cc: u64, narms: u64, div: u64, shorts: u64, span: Span) {`
Make panic in CC silencable (partial #478) 2015-12-05 08:53:00 +00:00			`if cx.current_level(CYCLOMATIC_COMPLEXITY) != Level::Allow {`
Rustup to syntax::errors changes 2015-12-31 20:39:03 +00:00			`cx.sess().span_note_without_error(span,`
			`&format!("Clippy encountered a bug calculating cyclomatic complexity \`
fmt clippy 2016-01-04 04:26:12 +00:00			(hide this message with `#[allow(cyclomatic_complexity)]`): cc \
fix cyclomatic complexity lint triggering because of short circuit operations 2016-03-08 14:10:02 +00:00			`= {}, arms = {}, div = {}, shorts = {}. Please file a bug report.",`
fmt clippy 2016-01-04 04:26:12 +00:00			`cc,`
			`narms,`
fix cyclomatic complexity lint triggering because of short circuit operations 2016-03-08 14:10:02 +00:00			`div,`
			`shorts));`
Make panic in CC silencable (partial #478) 2015-12-05 08:53:00 +00:00			`}`
			`}`