Projet_SETI_RISC-V/riscv-gnu-toolchain/gcc/libgo/go/cmd/gofmt/simplify.go

// Copyright 2010 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.

package main

import (
	"go/ast"
	"go/token"
	"reflect"
)

type simplifier struct{}

func (s simplifier) Visit(node ast.Node) ast.Visitor {
	switch n := node.(type) {
	case *ast.CompositeLit:
		// array, slice, and map composite literals may be simplified
		outer := n
		var keyType, eltType ast.Expr
		switch typ := outer.Type.(type) {
		case *ast.ArrayType:
			eltType = typ.Elt
		case *ast.MapType:
			keyType = typ.Key
			eltType = typ.Value
		}

		if eltType != nil {
			var ktyp reflect.Value
			if keyType != nil {
				ktyp = reflect.ValueOf(keyType)
			}
			typ := reflect.ValueOf(eltType)
			for i, x := range outer.Elts {
				px := &outer.Elts[i]
				// look at value of indexed/named elements
				if t, ok := x.(*ast.KeyValueExpr); ok {
					if keyType != nil {
						s.simplifyLiteral(ktyp, keyType, t.Key, &t.Key)
					}
					x = t.Value
					px = &t.Value
				}
				s.simplifyLiteral(typ, eltType, x, px)
			}
			// node was simplified - stop walk (there are no subnodes to simplify)
			return nil
		}

	case *ast.SliceExpr:
		// a slice expression of the form: s[a:len(s)]
		// can be simplified to: s[a:]
		// if s is "simple enough" (for now we only accept identifiers)
		//
		// Note: This may not be correct because len may have been redeclared in another
		//       file belonging to the same package. However, this is extremely unlikely
		//       and so far (April 2016, after years of supporting this rewrite feature)
		//       has never come up, so let's keep it working as is (see also #15153).
		if n.Max != nil {
			// - 3-index slices always require the 2nd and 3rd index
			break
		}
		if s, _ := n.X.(*ast.Ident); s != nil && s.Obj != nil {
			// the array/slice object is a single, resolved identifier
			if call, _ := n.High.(*ast.CallExpr); call != nil && len(call.Args) == 1 && !call.Ellipsis.IsValid() {
				// the high expression is a function call with a single argument
				if fun, _ := call.Fun.(*ast.Ident); fun != nil && fun.Name == "len" && fun.Obj == nil {
					// the function called is "len" and it is not locally defined; and
					// because we don't have dot imports, it must be the predefined len()
					if arg, _ := call.Args[0].(*ast.Ident); arg != nil && arg.Obj == s.Obj {
						// the len argument is the array/slice object
						n.High = nil
					}
				}
			}
		}
		// Note: We could also simplify slice expressions of the form s[0:b] to s[:b]
		//       but we leave them as is since sometimes we want to be very explicit
		//       about the lower bound.
		// An example where the 0 helps:
		//       x, y, z := b[0:2], b[2:4], b[4:6]
		// An example where it does not:
		//       x, y := b[:n], b[n:]

	case *ast.RangeStmt:
		// - a range of the form: for x, _ = range v {...}
		// can be simplified to: for x = range v {...}
		// - a range of the form: for _ = range v {...}
		// can be simplified to: for range v {...}
		if isBlank(n.Value) {
			n.Value = nil
		}
		if isBlank(n.Key) && n.Value == nil {
			n.Key = nil
		}
	}

	return s
}

func (s simplifier) simplifyLiteral(typ reflect.Value, astType, x ast.Expr, px *ast.Expr) {
	ast.Walk(s, x) // simplify x

	// if the element is a composite literal and its literal type
	// matches the outer literal's element type exactly, the inner
	// literal type may be omitted
	if inner, ok := x.(*ast.CompositeLit); ok {
		if match(nil, typ, reflect.ValueOf(inner.Type)) {
			inner.Type = nil
		}
	}
	// if the outer literal's element type is a pointer type *T
	// and the element is & of a composite literal of type T,
	// the inner &T may be omitted.
	if ptr, ok := astType.(*ast.StarExpr); ok {
		if addr, ok := x.(*ast.UnaryExpr); ok && addr.Op == token.AND {
			if inner, ok := addr.X.(*ast.CompositeLit); ok {
				if match(nil, reflect.ValueOf(ptr.X), reflect.ValueOf(inner.Type)) {
					inner.Type = nil // drop T
					*px = inner      // drop &
				}
			}
		}
	}
}

func isBlank(x ast.Expr) bool {
	ident, ok := x.(*ast.Ident)
	return ok && ident.Name == "_"
}

func simplify(f *ast.File) {
	// remove empty declarations such as "const ()", etc
	removeEmptyDeclGroups(f)

	var s simplifier
	ast.Walk(s, f)
}

func removeEmptyDeclGroups(f *ast.File) {
	i := 0
	for _, d := range f.Decls {
		if g, ok := d.(*ast.GenDecl); !ok || !isEmpty(f, g) {
			f.Decls[i] = d
			i++
		}
	}
	f.Decls = f.Decls[:i]
}

func isEmpty(f *ast.File, g *ast.GenDecl) bool {
	if g.Doc != nil || g.Specs != nil {
		return false
	}

	for _, c := range f.Comments {
		// if there is a comment in the declaration, it is not considered empty
		if g.Pos() <= c.Pos() && c.End() <= g.End() {
			return false
		}
	}

	return true
}
projet 2023-03-06 14:48:14 +01:00			`// Copyright 2010 The Go Authors. All rights reserved.`
			`// Use of this source code is governed by a BSD-style`
			`// license that can be found in the LICENSE file.`

			`package main`

			`import (`
			`"go/ast"`
			`"go/token"`
			`"reflect"`
			`)`

			`type simplifier struct{}`

			`func (s simplifier) Visit(node ast.Node) ast.Visitor {`
			`switch n := node.(type) {`
			`case *ast.CompositeLit:`
			`// array, slice, and map composite literals may be simplified`
			`outer := n`
			`var keyType, eltType ast.Expr`
			`switch typ := outer.Type.(type) {`
			`case *ast.ArrayType:`
			`eltType = typ.Elt`
			`case *ast.MapType:`
			`keyType = typ.Key`
			`eltType = typ.Value`
			`}`

			`if eltType != nil {`
			`var ktyp reflect.Value`
			`if keyType != nil {`
			`ktyp = reflect.ValueOf(keyType)`
			`}`
			`typ := reflect.ValueOf(eltType)`
			`for i, x := range outer.Elts {`
			`px := &outer.Elts[i]`
			`// look at value of indexed/named elements`
			`if t, ok := x.(*ast.KeyValueExpr); ok {`
			`if keyType != nil {`
			`s.simplifyLiteral(ktyp, keyType, t.Key, &t.Key)`
			`}`
			`x = t.Value`
			`px = &t.Value`
			`}`
			`s.simplifyLiteral(typ, eltType, x, px)`
			`}`
			`// node was simplified - stop walk (there are no subnodes to simplify)`
			`return nil`
			`}`

			`case *ast.SliceExpr:`
			`// a slice expression of the form: s[a:len(s)]`
			`// can be simplified to: s[a:]`
			`// if s is "simple enough" (for now we only accept identifiers)`
			`//`
			`// Note: This may not be correct because len may have been redeclared in another`
			`// file belonging to the same package. However, this is extremely unlikely`
			`// and so far (April 2016, after years of supporting this rewrite feature)`
			`// has never come up, so let's keep it working as is (see also #15153).`
			`if n.Max != nil {`
			`// - 3-index slices always require the 2nd and 3rd index`
			`break`
			`}`
			`if s, _ := n.X.(*ast.Ident); s != nil && s.Obj != nil {`
			`// the array/slice object is a single, resolved identifier`
			`if call, _ := n.High.(*ast.CallExpr); call != nil && len(call.Args) == 1 && !call.Ellipsis.IsValid() {`
			`// the high expression is a function call with a single argument`
			`if fun, _ := call.Fun.(*ast.Ident); fun != nil && fun.Name == "len" && fun.Obj == nil {`
			`// the function called is "len" and it is not locally defined; and`
			`// because we don't have dot imports, it must be the predefined len()`
			`if arg, _ := call.Args[0].(*ast.Ident); arg != nil && arg.Obj == s.Obj {`
			`// the len argument is the array/slice object`
			`n.High = nil`
			`}`
			`}`
			`}`
			`}`
			`// Note: We could also simplify slice expressions of the form s[0:b] to s[:b]`
			`// but we leave them as is since sometimes we want to be very explicit`
			`// about the lower bound.`
			`// An example where the 0 helps:`
			`// x, y, z := b[0:2], b[2:4], b[4:6]`
			`// An example where it does not:`
			`// x, y := b[:n], b[n:]`

			`case *ast.RangeStmt:`
			`// - a range of the form: for x, _ = range v {...}`
			`// can be simplified to: for x = range v {...}`
			`// - a range of the form: for _ = range v {...}`
			`// can be simplified to: for range v {...}`
			`if isBlank(n.Value) {`
			`n.Value = nil`
			`}`
			`if isBlank(n.Key) && n.Value == nil {`
			`n.Key = nil`
			`}`
			`}`

			`return s`
			`}`

			`func (s simplifier) simplifyLiteral(typ reflect.Value, astType, x ast.Expr, px *ast.Expr) {`
			`ast.Walk(s, x) // simplify x`

			`// if the element is a composite literal and its literal type`
			`// matches the outer literal's element type exactly, the inner`
			`// literal type may be omitted`
			`if inner, ok := x.(*ast.CompositeLit); ok {`
			`if match(nil, typ, reflect.ValueOf(inner.Type)) {`
			`inner.Type = nil`
			`}`
			`}`
			`// if the outer literal's element type is a pointer type *T`
			`// and the element is & of a composite literal of type T,`
			`// the inner &T may be omitted.`
			`if ptr, ok := astType.(*ast.StarExpr); ok {`
			`if addr, ok := x.(*ast.UnaryExpr); ok && addr.Op == token.AND {`
			`if inner, ok := addr.X.(*ast.CompositeLit); ok {`
			`if match(nil, reflect.ValueOf(ptr.X), reflect.ValueOf(inner.Type)) {`
			`inner.Type = nil // drop T`
			`*px = inner // drop &`
			`}`
			`}`
			`}`
			`}`
			`}`

			`func isBlank(x ast.Expr) bool {`
			`ident, ok := x.(*ast.Ident)`
			`return ok && ident.Name == "_"`
			`}`

			`func simplify(f *ast.File) {`
			`// remove empty declarations such as "const ()", etc`
			`removeEmptyDeclGroups(f)`

			`var s simplifier`
			`ast.Walk(s, f)`
			`}`

			`func removeEmptyDeclGroups(f *ast.File) {`
			`i := 0`
			`for _, d := range f.Decls {`
			`if g, ok := d.(*ast.GenDecl); !ok \|\| !isEmpty(f, g) {`
			`f.Decls[i] = d`
			`i++`
			`}`
			`}`
			`f.Decls = f.Decls[:i]`
			`}`

			`func isEmpty(f ast.File, g ast.GenDecl) bool {`
			`if g.Doc != nil \|\| g.Specs != nil {`
			`return false`
			`}`

			`for _, c := range f.Comments {`
			`// if there is a comment in the declaration, it is not considered empty`
			`if g.Pos() <= c.Pos() && c.End() <= g.End() {`
			`return false`
			`}`
			`}`

			`return true`
			`}`