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gitea/vendor/github.com/mgechev/revive/rule/cognitive-complexity.go
Lunny Xiao 4f63f283c4
Rename scripts to build and add revive command as a new build tool command (#10942)
Co-authored-by: techknowlogick <techknowlogick@gitea.io>
2020-04-03 22:29:12 +03:00

196 lines
4.6 KiB
Go

package rule
import (
"fmt"
"go/ast"
"go/token"
"github.com/mgechev/revive/lint"
"golang.org/x/tools/go/ast/astutil"
)
// CognitiveComplexityRule lints given else constructs.
type CognitiveComplexityRule struct{}
// Apply applies the rule to given file.
func (r *CognitiveComplexityRule) Apply(file *lint.File, arguments lint.Arguments) []lint.Failure {
var failures []lint.Failure
const expectedArgumentsCount = 1
if len(arguments) < expectedArgumentsCount {
panic(fmt.Sprintf("not enough arguments for cognitive-complexity, expected %d, got %d", expectedArgumentsCount, len(arguments)))
}
complexity, ok := arguments[0].(int64)
if !ok {
panic(fmt.Sprintf("invalid argument type for cognitive-complexity, expected int64, got %T", arguments[0]))
}
linter := cognitiveComplexityLinter{
file: file,
maxComplexity: int(complexity),
onFailure: func(failure lint.Failure) {
failures = append(failures, failure)
},
}
linter.lint()
return failures
}
// Name returns the rule name.
func (r *CognitiveComplexityRule) Name() string {
return "cognitive-complexity"
}
type cognitiveComplexityLinter struct {
file *lint.File
maxComplexity int
onFailure func(lint.Failure)
}
func (w cognitiveComplexityLinter) lint() {
f := w.file
for _, decl := range f.AST.Decls {
if fn, ok := decl.(*ast.FuncDecl); ok {
v := cognitiveComplexityVisitor{}
c := v.subTreeComplexity(fn.Body)
if c > w.maxComplexity {
w.onFailure(lint.Failure{
Confidence: 1,
Category: "maintenance",
Failure: fmt.Sprintf("function %s has cognitive complexity %d (> max enabled %d)", funcName(fn), c, w.maxComplexity),
Node: fn,
})
}
}
}
}
type cognitiveComplexityVisitor struct {
complexity int
nestingLevel int
}
// subTreeComplexity calculates the cognitive complexity of an AST-subtree.
func (v cognitiveComplexityVisitor) subTreeComplexity(n ast.Node) int {
ast.Walk(&v, n)
return v.complexity
}
// Visit implements the ast.Visitor interface.
func (v *cognitiveComplexityVisitor) Visit(n ast.Node) ast.Visitor {
switch n := n.(type) {
case *ast.IfStmt:
targets := []ast.Node{n.Cond, n.Body, n.Else}
v.walk(1, targets...)
return nil
case *ast.ForStmt:
targets := []ast.Node{n.Cond, n.Body}
v.walk(1, targets...)
return nil
case *ast.RangeStmt:
v.walk(1, n.Body)
return nil
case *ast.SelectStmt:
v.walk(1, n.Body)
return nil
case *ast.SwitchStmt:
v.walk(1, n.Body)
return nil
case *ast.TypeSwitchStmt:
v.walk(1, n.Body)
return nil
case *ast.FuncLit:
v.walk(0, n.Body) // do not increment the complexity, just do the nesting
return nil
case *ast.BinaryExpr:
v.complexity += v.binExpComplexity(n)
return nil // skip visiting binexp sub-tree (already visited by binExpComplexity)
case *ast.BranchStmt:
if n.Label != nil {
v.complexity += 1
}
}
// TODO handle (at least) direct recursion
return v
}
func (v *cognitiveComplexityVisitor) walk(complexityIncrement int, targets ...ast.Node) {
v.complexity += complexityIncrement + v.nestingLevel
nesting := v.nestingLevel
v.nestingLevel++
for _, t := range targets {
if t == nil {
continue
}
ast.Walk(v, t)
}
v.nestingLevel = nesting
}
func (cognitiveComplexityVisitor) binExpComplexity(n *ast.BinaryExpr) int {
calculator := binExprComplexityCalculator{opsStack: []token.Token{}}
astutil.Apply(n, calculator.pre, calculator.post)
return calculator.complexity
}
type binExprComplexityCalculator struct {
complexity int
opsStack []token.Token // stack of bool operators
subexpStarted bool
}
func (becc *binExprComplexityCalculator) pre(c *astutil.Cursor) bool {
switch n := c.Node().(type) {
case *ast.BinaryExpr:
isBoolOp := n.Op == token.LAND || n.Op == token.LOR
if !isBoolOp {
break
}
ops := len(becc.opsStack)
// if
// is the first boolop in the expression OR
// is the first boolop inside a subexpression (...) OR
// is not the same to the previous one
// then
// increment complexity
if ops == 0 || becc.subexpStarted || n.Op != becc.opsStack[ops-1] {
becc.complexity++
becc.subexpStarted = false
}
becc.opsStack = append(becc.opsStack, n.Op)
case *ast.ParenExpr:
becc.subexpStarted = true
}
return true
}
func (becc *binExprComplexityCalculator) post(c *astutil.Cursor) bool {
switch n := c.Node().(type) {
case *ast.BinaryExpr:
isBoolOp := n.Op == token.LAND || n.Op == token.LOR
if !isBoolOp {
break
}
ops := len(becc.opsStack)
if ops > 0 {
becc.opsStack = becc.opsStack[:ops-1]
}
case *ast.ParenExpr:
becc.subexpStarted = false
}
return true
}