github.com/razvanm/vanadium-go-1.3@v0.0.0-20160721203343-4a65068e5915/src/cmd/gofmt/simplify.go (about)

     1  // Copyright 2010 The Go Authors. All rights reserved.
     2  // Use of this source code is governed by a BSD-style
     3  // license that can be found in the LICENSE file.
     4  
     5  package main
     6  
     7  import (
     8  	"go/ast"
     9  	"go/token"
    10  	"reflect"
    11  )
    12  
    13  type simplifier struct {
    14  	hasDotImport bool // package file contains: import . "some/import/path"
    15  }
    16  
    17  func (s *simplifier) Visit(node ast.Node) ast.Visitor {
    18  	switch n := node.(type) {
    19  	case *ast.CompositeLit:
    20  		// array, slice, and map composite literals may be simplified
    21  		outer := n
    22  		var eltType ast.Expr
    23  		switch typ := outer.Type.(type) {
    24  		case *ast.ArrayType:
    25  			eltType = typ.Elt
    26  		case *ast.MapType:
    27  			eltType = typ.Value
    28  		}
    29  
    30  		if eltType != nil {
    31  			typ := reflect.ValueOf(eltType)
    32  			for i, x := range outer.Elts {
    33  				px := &outer.Elts[i]
    34  				// look at value of indexed/named elements
    35  				if t, ok := x.(*ast.KeyValueExpr); ok {
    36  					x = t.Value
    37  					px = &t.Value
    38  				}
    39  				ast.Walk(s, x) // simplify x
    40  				// if the element is a composite literal and its literal type
    41  				// matches the outer literal's element type exactly, the inner
    42  				// literal type may be omitted
    43  				if inner, ok := x.(*ast.CompositeLit); ok {
    44  					if match(nil, typ, reflect.ValueOf(inner.Type)) {
    45  						inner.Type = nil
    46  					}
    47  				}
    48  				// if the outer literal's element type is a pointer type *T
    49  				// and the element is & of a composite literal of type T,
    50  				// the inner &T may be omitted.
    51  				if ptr, ok := eltType.(*ast.StarExpr); ok {
    52  					if addr, ok := x.(*ast.UnaryExpr); ok && addr.Op == token.AND {
    53  						if inner, ok := addr.X.(*ast.CompositeLit); ok {
    54  							if match(nil, reflect.ValueOf(ptr.X), reflect.ValueOf(inner.Type)) {
    55  								inner.Type = nil // drop T
    56  								*px = inner      // drop &
    57  							}
    58  						}
    59  					}
    60  				}
    61  			}
    62  
    63  			// node was simplified - stop walk (there are no subnodes to simplify)
    64  			return nil
    65  		}
    66  
    67  	case *ast.SliceExpr:
    68  		// a slice expression of the form: s[a:len(s)]
    69  		// can be simplified to: s[a:]
    70  		// if s is "simple enough" (for now we only accept identifiers)
    71  		if n.Max != nil || s.hasDotImport {
    72  			// - 3-index slices always require the 2nd and 3rd index
    73  			// - if dot imports are present, we cannot be certain that an
    74  			//   unresolved "len" identifier refers to the predefined len()
    75  			break
    76  		}
    77  		if s, _ := n.X.(*ast.Ident); s != nil && s.Obj != nil {
    78  			// the array/slice object is a single, resolved identifier
    79  			if call, _ := n.High.(*ast.CallExpr); call != nil && len(call.Args) == 1 && !call.Ellipsis.IsValid() {
    80  				// the high expression is a function call with a single argument
    81  				if fun, _ := call.Fun.(*ast.Ident); fun != nil && fun.Name == "len" && fun.Obj == nil {
    82  					// the function called is "len" and it is not locally defined; and
    83  					// because we don't have dot imports, it must be the predefined len()
    84  					if arg, _ := call.Args[0].(*ast.Ident); arg != nil && arg.Obj == s.Obj {
    85  						// the len argument is the array/slice object
    86  						n.High = nil
    87  					}
    88  				}
    89  			}
    90  		}
    91  		// Note: We could also simplify slice expressions of the form s[0:b] to s[:b]
    92  		//       but we leave them as is since sometimes we want to be very explicit
    93  		//       about the lower bound.
    94  		// An example where the 0 helps:
    95  		//       x, y, z := b[0:2], b[2:4], b[4:6]
    96  		// An example where it does not:
    97  		//       x, y := b[:n], b[n:]
    98  
    99  	case *ast.RangeStmt:
   100  		// - a range of the form: for x, _ = range v {...}
   101  		// can be simplified to: for x = range v {...}
   102  		// - a range of the form: for _ = range v {...}
   103  		// can be simplified to: for range v {...}
   104  		if isBlank(n.Value) {
   105  			n.Value = nil
   106  		}
   107  		if isBlank(n.Key) && n.Value == nil {
   108  			n.Key = nil
   109  		}
   110  	}
   111  
   112  	return s
   113  }
   114  
   115  func isBlank(x ast.Expr) bool {
   116  	ident, ok := x.(*ast.Ident)
   117  	return ok && ident.Name == "_"
   118  }
   119  
   120  func simplify(f *ast.File) {
   121  	var s simplifier
   122  
   123  	// determine if f contains dot imports
   124  	for _, imp := range f.Imports {
   125  		if imp.Name != nil && imp.Name.Name == "." {
   126  			s.hasDotImport = true
   127  			break
   128  		}
   129  	}
   130  
   131  	// remove empty declarations such as "const ()", etc
   132  	removeEmptyDeclGroups(f)
   133  
   134  	ast.Walk(&s, f)
   135  }
   136  
   137  func removeEmptyDeclGroups(f *ast.File) {
   138  	i := 0
   139  	for _, d := range f.Decls {
   140  		if g, ok := d.(*ast.GenDecl); !ok || !isEmpty(f, g) {
   141  			f.Decls[i] = d
   142  			i++
   143  		}
   144  	}
   145  	f.Decls = f.Decls[:i]
   146  }
   147  
   148  func isEmpty(f *ast.File, g *ast.GenDecl) bool {
   149  	if g.Doc != nil || g.Specs != nil {
   150  		return false
   151  	}
   152  
   153  	for _, c := range f.Comments {
   154  		// if there is a comment in the declaration, it is not considered empty
   155  		if g.Pos() <= c.Pos() && c.End() <= g.End() {
   156  			return false
   157  		}
   158  	}
   159  
   160  	return true
   161  }