github.com/aloncn/graphics-go@v0.0.1/src/go/types/typestring.go (about)

     1  // Copyright 2013 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  // This file implements printing of types.
     6  
     7  package types
     8  
     9  import (
    10  	"bytes"
    11  	"fmt"
    12  )
    13  
    14  // A Qualifier controls how named package-level objects are printed in
    15  // calls to TypeString, ObjectString, and SelectionString.
    16  //
    17  // These three formatting routines call the Qualifier for each
    18  // package-level object O, and if the Qualifier returns a non-empty
    19  // string p, the object is printed in the form p.O.
    20  // If it returns an empty string, only the object name O is printed.
    21  //
    22  // Using a nil Qualifier is equivalent to using (*Package).Path: the
    23  // object is qualified by the import path, e.g., "encoding/json.Marshal".
    24  //
    25  type Qualifier func(*Package) string
    26  
    27  // RelativeTo(pkg) returns a Qualifier that fully qualifies members of
    28  // all packages other than pkg.
    29  func RelativeTo(pkg *Package) Qualifier {
    30  	if pkg == nil {
    31  		return nil
    32  	}
    33  	return func(other *Package) string {
    34  		if pkg == other {
    35  			return "" // same package; unqualified
    36  		}
    37  		return other.Path()
    38  	}
    39  }
    40  
    41  // If gcCompatibilityMode is set, printing of types is modified
    42  // to match the representation of some types in the gc compiler:
    43  //
    44  //	- byte and rune lose their alias name and simply stand for
    45  //	  uint8 and int32 respectively
    46  //	- embedded interfaces get flattened (the embedding info is lost,
    47  //	  and certain recursive interface types cannot be printed anymore)
    48  //
    49  // This makes it easier to compare packages computed with the type-
    50  // checker vs packages imported from gc export data.
    51  //
    52  // Caution: This flag affects all uses of WriteType, globally.
    53  // It is only provided for testing in conjunction with
    54  // gc-generated data.
    55  //
    56  // This flag is exported in the x/tools/go/types package. We don't
    57  // need it at the moment in the std repo and so we don't export it
    58  // anymore. We should eventually try to remove it altogether.
    59  var gcCompatibilityMode bool
    60  
    61  // TypeString returns the string representation of typ.
    62  // The Qualifier controls the printing of
    63  // package-level objects, and may be nil.
    64  func TypeString(typ Type, qf Qualifier) string {
    65  	var buf bytes.Buffer
    66  	WriteType(&buf, typ, qf)
    67  	return buf.String()
    68  }
    69  
    70  // WriteType writes the string representation of typ to buf.
    71  // The Qualifier controls the printing of
    72  // package-level objects, and may be nil.
    73  func WriteType(buf *bytes.Buffer, typ Type, qf Qualifier) {
    74  	writeType(buf, typ, qf, make([]Type, 0, 8))
    75  }
    76  
    77  func writeType(buf *bytes.Buffer, typ Type, qf Qualifier, visited []Type) {
    78  	// Theoretically, this is a quadratic lookup algorithm, but in
    79  	// practice deeply nested composite types with unnamed component
    80  	// types are uncommon. This code is likely more efficient than
    81  	// using a map.
    82  	for _, t := range visited {
    83  		if t == typ {
    84  			fmt.Fprintf(buf, "○%T", typ) // cycle to typ
    85  			return
    86  		}
    87  	}
    88  	visited = append(visited, typ)
    89  
    90  	switch t := typ.(type) {
    91  	case nil:
    92  		buf.WriteString("<nil>")
    93  
    94  	case *Basic:
    95  		if t.kind == UnsafePointer {
    96  			buf.WriteString("unsafe.")
    97  		}
    98  		if gcCompatibilityMode {
    99  			// forget the alias names
   100  			switch t.kind {
   101  			case Byte:
   102  				t = Typ[Uint8]
   103  			case Rune:
   104  				t = Typ[Int32]
   105  			}
   106  		}
   107  		buf.WriteString(t.name)
   108  
   109  	case *Array:
   110  		fmt.Fprintf(buf, "[%d]", t.len)
   111  		writeType(buf, t.elem, qf, visited)
   112  
   113  	case *Slice:
   114  		buf.WriteString("[]")
   115  		writeType(buf, t.elem, qf, visited)
   116  
   117  	case *Struct:
   118  		buf.WriteString("struct{")
   119  		for i, f := range t.fields {
   120  			if i > 0 {
   121  				buf.WriteString("; ")
   122  			}
   123  			if !f.anonymous {
   124  				buf.WriteString(f.name)
   125  				buf.WriteByte(' ')
   126  			}
   127  			writeType(buf, f.typ, qf, visited)
   128  			if tag := t.Tag(i); tag != "" {
   129  				fmt.Fprintf(buf, " %q", tag)
   130  			}
   131  		}
   132  		buf.WriteByte('}')
   133  
   134  	case *Pointer:
   135  		buf.WriteByte('*')
   136  		writeType(buf, t.base, qf, visited)
   137  
   138  	case *Tuple:
   139  		writeTuple(buf, t, false, qf, visited)
   140  
   141  	case *Signature:
   142  		buf.WriteString("func")
   143  		writeSignature(buf, t, qf, visited)
   144  
   145  	case *Interface:
   146  		// We write the source-level methods and embedded types rather
   147  		// than the actual method set since resolved method signatures
   148  		// may have non-printable cycles if parameters have anonymous
   149  		// interface types that (directly or indirectly) embed the
   150  		// current interface. For instance, consider the result type
   151  		// of m:
   152  		//
   153  		//     type T interface{
   154  		//         m() interface{ T }
   155  		//     }
   156  		//
   157  		buf.WriteString("interface{")
   158  		if gcCompatibilityMode {
   159  			// print flattened interface
   160  			// (useful to compare against gc-generated interfaces)
   161  			for i, m := range t.allMethods {
   162  				if i > 0 {
   163  					buf.WriteString("; ")
   164  				}
   165  				buf.WriteString(m.name)
   166  				writeSignature(buf, m.typ.(*Signature), qf, visited)
   167  			}
   168  		} else {
   169  			// print explicit interface methods and embedded types
   170  			for i, m := range t.methods {
   171  				if i > 0 {
   172  					buf.WriteString("; ")
   173  				}
   174  				buf.WriteString(m.name)
   175  				writeSignature(buf, m.typ.(*Signature), qf, visited)
   176  			}
   177  			for i, typ := range t.embeddeds {
   178  				if i > 0 || len(t.methods) > 0 {
   179  					buf.WriteString("; ")
   180  				}
   181  				writeType(buf, typ, qf, visited)
   182  			}
   183  		}
   184  		buf.WriteByte('}')
   185  
   186  	case *Map:
   187  		buf.WriteString("map[")
   188  		writeType(buf, t.key, qf, visited)
   189  		buf.WriteByte(']')
   190  		writeType(buf, t.elem, qf, visited)
   191  
   192  	case *Chan:
   193  		var s string
   194  		var parens bool
   195  		switch t.dir {
   196  		case SendRecv:
   197  			s = "chan "
   198  			// chan (<-chan T) requires parentheses
   199  			if c, _ := t.elem.(*Chan); c != nil && c.dir == RecvOnly {
   200  				parens = true
   201  			}
   202  		case SendOnly:
   203  			s = "chan<- "
   204  		case RecvOnly:
   205  			s = "<-chan "
   206  		default:
   207  			panic("unreachable")
   208  		}
   209  		buf.WriteString(s)
   210  		if parens {
   211  			buf.WriteByte('(')
   212  		}
   213  		writeType(buf, t.elem, qf, visited)
   214  		if parens {
   215  			buf.WriteByte(')')
   216  		}
   217  
   218  	case *Named:
   219  		s := "<Named w/o object>"
   220  		if obj := t.obj; obj != nil {
   221  			if obj.pkg != nil {
   222  				writePackage(buf, obj.pkg, qf)
   223  			}
   224  			// TODO(gri): function-local named types should be displayed
   225  			// differently from named types at package level to avoid
   226  			// ambiguity.
   227  			s = obj.name
   228  		}
   229  		buf.WriteString(s)
   230  
   231  	default:
   232  		// For externally defined implementations of Type.
   233  		buf.WriteString(t.String())
   234  	}
   235  }
   236  
   237  func writeTuple(buf *bytes.Buffer, tup *Tuple, variadic bool, qf Qualifier, visited []Type) {
   238  	buf.WriteByte('(')
   239  	if tup != nil {
   240  		for i, v := range tup.vars {
   241  			if i > 0 {
   242  				buf.WriteString(", ")
   243  			}
   244  			if v.name != "" {
   245  				buf.WriteString(v.name)
   246  				buf.WriteByte(' ')
   247  			}
   248  			typ := v.typ
   249  			if variadic && i == len(tup.vars)-1 {
   250  				if s, ok := typ.(*Slice); ok {
   251  					buf.WriteString("...")
   252  					typ = s.elem
   253  				} else {
   254  					// special case:
   255  					// append(s, "foo"...) leads to signature func([]byte, string...)
   256  					if t, ok := typ.Underlying().(*Basic); !ok || t.kind != String {
   257  						panic("internal error: string type expected")
   258  					}
   259  					writeType(buf, typ, qf, visited)
   260  					buf.WriteString("...")
   261  					continue
   262  				}
   263  			}
   264  			writeType(buf, typ, qf, visited)
   265  		}
   266  	}
   267  	buf.WriteByte(')')
   268  }
   269  
   270  // WriteSignature writes the representation of the signature sig to buf,
   271  // without a leading "func" keyword.
   272  // The Qualifier controls the printing of
   273  // package-level objects, and may be nil.
   274  func WriteSignature(buf *bytes.Buffer, sig *Signature, qf Qualifier) {
   275  	writeSignature(buf, sig, qf, make([]Type, 0, 8))
   276  }
   277  
   278  func writeSignature(buf *bytes.Buffer, sig *Signature, qf Qualifier, visited []Type) {
   279  	writeTuple(buf, sig.params, sig.variadic, qf, visited)
   280  
   281  	n := sig.results.Len()
   282  	if n == 0 {
   283  		// no result
   284  		return
   285  	}
   286  
   287  	buf.WriteByte(' ')
   288  	if n == 1 && sig.results.vars[0].name == "" {
   289  		// single unnamed result
   290  		writeType(buf, sig.results.vars[0].typ, qf, visited)
   291  		return
   292  	}
   293  
   294  	// multiple or named result(s)
   295  	writeTuple(buf, sig.results, false, qf, visited)
   296  }