// Copyright 2009 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. // DWARF type information structures. // The format is heavily biased toward C, but for simplicity // the String methods use a pseudo-Go syntax. package dwarf import "strconv" // A Type conventionally represents a pointer to any of the // specific Type structures (CharType, StructType, etc.). type Type interface { Common() *CommonType String() string Size() int64 } // A CommonType holds fields common to multiple types. // If a field is not known or not applicable for a given type, // the zero value is used. type CommonType struct { ByteSize int64 // size of value of this type, in bytes Name string // name that can be used to refer to type } func (c *CommonType) Common() *CommonType { return c } func (c *CommonType) Size() int64 { return c.ByteSize } // Basic types // A BasicType holds fields common to all basic types. // // See the documentation for StructField for more info on the interpretation of // the BitSize/BitOffset/DataBitOffset fields. type BasicType struct { CommonType BitSize int64 BitOffset int64 DataBitOffset int64 } func (b *BasicType) Basic() *BasicType { return b } func (t *BasicType) String() string { if t.Name != "" { return t.Name } return "?" } // A CharType represents a signed character type. type CharType struct { BasicType } // A UcharType represents an unsigned character type. type UcharType struct { BasicType } // An IntType represents a signed integer type. type IntType struct { BasicType } // A UintType represents an unsigned integer type. type UintType struct { BasicType } // A FloatType represents a floating point type. type FloatType struct { BasicType } // A ComplexType represents a complex floating point type. type ComplexType struct { BasicType } // A BoolType represents a boolean type. type BoolType struct { BasicType } // An AddrType represents a machine address type. type AddrType struct { BasicType } // An UnspecifiedType represents an implicit, unknown, ambiguous or nonexistent type. type UnspecifiedType struct { BasicType } // qualifiers // A QualType represents a type that has the C/C++ "const", "restrict", or "volatile" qualifier. type QualType struct { CommonType Qual string Type Type } func (t *QualType) String() string { return t.Qual + " " + t.Type.String() } func (t *QualType) Size() int64 { return t.Type.Size() } // An ArrayType represents a fixed size array type. type ArrayType struct { CommonType Type Type StrideBitSize int64 // if > 0, number of bits to hold each element Count int64 // if == -1, an incomplete array, like char x[]. } func (t *ArrayType) String() string { return "[" + strconv.FormatInt(t.Count, 10) + "]" + t.Type.String() } func (t *ArrayType) Size() int64 { if t.Count == -1 { return 0 } return t.Count * t.Type.Size() } // A VoidType represents the C void type. type VoidType struct { CommonType } func (t *VoidType) String() string { return "void" } // A PtrType represents a pointer type. type PtrType struct { CommonType Type Type } func (t *PtrType) String() string { return "*" + t.Type.String() } // A StructType represents a struct, union, or C++ class type. type StructType struct { CommonType StructName string Kind string // "struct", "union", or "class". Field []*StructField Incomplete bool // if true, struct, union, class is declared but not defined } // A StructField represents a field in a struct, union, or C++ class type. // // Bit Fields // // The BitSize, BitOffset, and DataBitOffset fields describe the bit // size and offset of data members declared as bit fields in C/C++ // struct/union/class types. // // BitSize is the number of bits in the bit field. // // DataBitOffset, if non-zero, is the number of bits from the start of // the enclosing entity (e.g. containing struct/class/union) to the // start of the bit field. This corresponds to the DW_AT_data_bit_offset // DWARF attribute that was introduced in DWARF 4. // // BitOffset, if non-zero, is the number of bits between the most // significant bit of the storage unit holding the bit field to the // most significant bit of the bit field. Here "storage unit" is the // type name before the bit field (for a field "unsigned x:17", the // storage unit is "unsigned"). BitOffset values can vary depending on // the endianness of the system. BitOffset corresponds to the // DW_AT_bit_offset DWARF attribute that was deprecated in DWARF 4 and // removed in DWARF 5. // // At most one of DataBitOffset and BitOffset will be non-zero; // DataBitOffset/BitOffset will only be non-zero if BitSize is // non-zero. Whether a C compiler uses one or the other // will depend on compiler vintage and command line options. // // Here is an example of C/C++ bit field use, along with what to // expect in terms of DWARF bit offset info. Consider this code: // // struct S { // int q; // int j:5; // int k:6; // int m:5; // int n:8; // } s; // // For the code above, one would expect to see the following for // DW_AT_bit_offset values (using GCC 8): // // Little | Big // Endian | Endian // | // "j": 27 | 0 // "k": 21 | 5 // "m": 16 | 11 // "n": 8 | 16 // // Note that in the above the offsets are purely with respect to the // containing storage unit for j/k/m/n -- these values won't vary based // on the size of prior data members in the containing struct. // // If the compiler emits DW_AT_data_bit_offset, the expected values // would be: // // "j": 32 // "k": 37 // "m": 43 // "n": 48 // // Here the value 32 for "j" reflects the fact that the bit field is // preceded by other data members (recall that DW_AT_data_bit_offset // values are relative to the start of the containing struct). Hence // DW_AT_data_bit_offset values can be quite large for structs with // many fields. // // DWARF also allow for the possibility of base types that have // non-zero bit size and bit offset, so this information is also // captured for base types, but it is worth noting that it is not // possible to trigger this behavior using mainstream languages. // type StructField struct { Name string Type Type ByteOffset int64 ByteSize int64 // usually zero; use Type.Size() for normal fields BitOffset int64 DataBitOffset int64 BitSize int64 // zero if not a bit field } func (t *StructType) String() string { if t.StructName != "" { return t.Kind + " " + t.StructName } return t.Defn() } func (f *StructField) bitOffset() int64 { if f.BitOffset != 0 { return f.BitOffset } return f.DataBitOffset } func (t *StructType) Defn() string { s := t.Kind if t.StructName != "" { s += " " + t.StructName } if t.Incomplete { s += " /*incomplete*/" return s } s += " {" for i, f := range t.Field { if i > 0 { s += "; " } s += f.Name + " " + f.Type.String() s += "@" + strconv.FormatInt(f.ByteOffset, 10) if f.BitSize > 0 { s += " : " + strconv.FormatInt(f.BitSize, 10) s += "@" + strconv.FormatInt(f.bitOffset(), 10) } } s += "}" return s } // An EnumType represents an enumerated type. // The only indication of its native integer type is its ByteSize // (inside CommonType). type EnumType struct { CommonType EnumName string Val []*EnumValue } // An EnumValue represents a single enumeration value. type EnumValue struct { Name string Val int64 } func (t *EnumType) String() string { s := "enum" if t.EnumName != "" { s += " " + t.EnumName } s += " {" for i, v := range t.Val { if i > 0 { s += "; " } s += v.Name + "=" + strconv.FormatInt(v.Val, 10) } s += "}" return s } // A FuncType represents a function type. type FuncType struct { CommonType ReturnType Type ParamType []Type } func (t *FuncType) String() string { s := "func(" for i, t := range t.ParamType { if i > 0 { s += ", " } s += t.String() } s += ")" if t.ReturnType != nil { s += " " + t.ReturnType.String() } return s } // A DotDotDotType represents the variadic ... function parameter. type DotDotDotType struct { CommonType } func (t *DotDotDotType) String() string { return "..." } // A TypedefType represents a named type. type TypedefType struct { CommonType Type Type } func (t *TypedefType) String() string { return t.Name } func (t *TypedefType) Size() int64 { return t.Type.Size() } // An UnsupportedType is a placeholder returned in situations where we // encounter a type that isn't supported. type UnsupportedType struct { CommonType Tag Tag } func (t *UnsupportedType) String() string { if t.Name != "" { return t.Name } return t.Name + "(unsupported type " + t.Tag.String() + ")" } // typeReader is used to read from either the info section or the // types section. type typeReader interface { Seek(Offset) Next() (*Entry, error) clone() typeReader offset() Offset // AddressSize returns the size in bytes of addresses in the current // compilation unit. AddressSize() int } // Type reads the type at off in the DWARF ``info'' section. func (d *Data) Type(off Offset) (Type, error) { return d.readType("info", d.Reader(), off, d.typeCache, nil) } type typeFixer struct { typedefs []*TypedefType arraytypes []*Type } func (tf *typeFixer) recordArrayType(t *Type) { if t == nil { return } _, ok := (*t).(*ArrayType) if ok { tf.arraytypes = append(tf.arraytypes, t) } } func (tf *typeFixer) apply() { for _, t := range tf.typedefs { t.Common().ByteSize = t.Type.Size() } for _, t := range tf.arraytypes { zeroArray(t) } } // readType reads a type from r at off of name. It adds types to the // type cache, appends new typedef types to typedefs, and computes the // sizes of types. Callers should pass nil for typedefs; this is used // for internal recursion. func (d *Data) readType(name string, r typeReader, off Offset, typeCache map[Offset]Type, fixups *typeFixer) (Type, error) { if t, ok := typeCache[off]; ok { return t, nil } r.Seek(off) e, err := r.Next() if err != nil { return nil, err } addressSize := r.AddressSize() if e == nil || e.Offset != off { return nil, DecodeError{name, off, "no type at offset"} } // If this is the root of the recursion, prepare to resolve // typedef sizes and perform other fixups once the recursion is // done. This must be done after the type graph is constructed // because it may need to resolve cycles in a different order than // readType encounters them. if fixups == nil { var fixer typeFixer defer func() { fixer.apply() }() fixups = &fixer } // Parse type from Entry. // Must always set typeCache[off] before calling // d.readType recursively, to handle circular types correctly. var typ Type nextDepth := 0 // Get next child; set err if error happens. next := func() *Entry { if !e.Children { return nil } // Only return direct children. // Skip over composite entries that happen to be nested // inside this one. Most DWARF generators wouldn't generate // such a thing, but clang does. // See golang.org/issue/6472. for { kid, err1 := r.Next() if err1 != nil { err = err1 return nil } if kid == nil { err = DecodeError{name, r.offset(), "unexpected end of DWARF entries"} return nil } if kid.Tag == 0 { if nextDepth > 0 { nextDepth-- continue } return nil } if kid.Children { nextDepth++ } if nextDepth > 0 { continue } return kid } } // Get Type referred to by Entry's AttrType field. // Set err if error happens. Not having a type is an error. typeOf := func(e *Entry) Type { tval := e.Val(AttrType) var t Type switch toff := tval.(type) { case Offset: if t, err = d.readType(name, r.clone(), toff, typeCache, fixups); err != nil { return nil } case uint64: if t, err = d.sigToType(toff); err != nil { return nil } default: // It appears that no Type means "void". return new(VoidType) } return t } switch e.Tag { case TagArrayType: // Multi-dimensional array. (DWARF v2 §5.4) // Attributes: // AttrType:subtype [required] // AttrStrideSize: size in bits of each element of the array // AttrByteSize: size of entire array // Children: // TagSubrangeType or TagEnumerationType giving one dimension. // dimensions are in left to right order. t := new(ArrayType) typ = t typeCache[off] = t if t.Type = typeOf(e); err != nil { goto Error } t.StrideBitSize, _ = e.Val(AttrStrideSize).(int64) // Accumulate dimensions, var dims []int64 for kid := next(); kid != nil; kid = next() { // TODO(rsc): Can also be TagEnumerationType // but haven't seen that in the wild yet. switch kid.Tag { case TagSubrangeType: count, ok := kid.Val(AttrCount).(int64) if !ok { // Old binaries may have an upper bound instead. count, ok = kid.Val(AttrUpperBound).(int64) if ok { count++ // Length is one more than upper bound. } else if len(dims) == 0 { count = -1 // As in x[]. } } dims = append(dims, count) case TagEnumerationType: err = DecodeError{name, kid.Offset, "cannot handle enumeration type as array bound"} goto Error } } if len(dims) == 0 { // LLVM generates this for x[]. dims = []int64{-1} } t.Count = dims[0] for i := len(dims) - 1; i >= 1; i-- { t.Type = &ArrayType{Type: t.Type, Count: dims[i]} } case TagBaseType: // Basic type. (DWARF v2 §5.1) // Attributes: // AttrName: name of base type in programming language of the compilation unit [required] // AttrEncoding: encoding value for type (encFloat etc) [required] // AttrByteSize: size of type in bytes [required] // AttrBitOffset: bit offset of value within containing storage unit // AttrDataBitOffset: bit offset of value within containing storage unit // AttrBitSize: size in bits // // For most languages BitOffset/DataBitOffset/BitSize will not be present // for base types. name, _ := e.Val(AttrName).(string) enc, ok := e.Val(AttrEncoding).(int64) if !ok { err = DecodeError{name, e.Offset, "missing encoding attribute for " + name} goto Error } switch enc { default: err = DecodeError{name, e.Offset, "unrecognized encoding attribute value"} goto Error case encAddress: typ = new(AddrType) case encBoolean: typ = new(BoolType) case encComplexFloat: typ = new(ComplexType) if name == "complex" { // clang writes out 'complex' instead of 'complex float' or 'complex double'. // clang also writes out a byte size that we can use to distinguish. // See issue 8694. switch byteSize, _ := e.Val(AttrByteSize).(int64); byteSize { case 8: name = "complex float" case 16: name = "complex double" } } case encFloat: typ = new(FloatType) case encSigned: typ = new(IntType) case encUnsigned: typ = new(UintType) case encSignedChar: typ = new(CharType) case encUnsignedChar: typ = new(UcharType) } typeCache[off] = typ t := typ.(interface { Basic() *BasicType }).Basic() t.Name = name t.BitSize, _ = e.Val(AttrBitSize).(int64) haveBitOffset := false haveDataBitOffset := false t.BitOffset, haveBitOffset = e.Val(AttrBitOffset).(int64) t.DataBitOffset, haveDataBitOffset = e.Val(AttrDataBitOffset).(int64) if haveBitOffset && haveDataBitOffset { err = DecodeError{name, e.Offset, "duplicate bit offset attributes"} goto Error } case TagClassType, TagStructType, TagUnionType: // Structure, union, or class type. (DWARF v2 §5.5) // Attributes: // AttrName: name of struct, union, or class // AttrByteSize: byte size [required] // AttrDeclaration: if true, struct/union/class is incomplete // Children: // TagMember to describe one member. // AttrName: name of member [required] // AttrType: type of member [required] // AttrByteSize: size in bytes // AttrBitOffset: bit offset within bytes for bit fields // AttrDataBitOffset: field bit offset relative to struct start // AttrBitSize: bit size for bit fields // AttrDataMemberLoc: location within struct [required for struct, class] // There is much more to handle C++, all ignored for now. t := new(StructType) typ = t typeCache[off] = t switch e.Tag { case TagClassType: t.Kind = "class" case TagStructType: t.Kind = "struct" case TagUnionType: t.Kind = "union" } t.StructName, _ = e.Val(AttrName).(string) t.Incomplete = e.Val(AttrDeclaration) != nil t.Field = make([]*StructField, 0, 8) var lastFieldType *Type var lastFieldBitSize int64 var lastFieldByteOffset int64 for kid := next(); kid != nil; kid = next() { if kid.Tag != TagMember { continue } f := new(StructField) if f.Type = typeOf(kid); err != nil { goto Error } switch loc := kid.Val(AttrDataMemberLoc).(type) { case []byte: // TODO: Should have original compilation // unit here, not unknownFormat. b := makeBuf(d, unknownFormat{}, "location", 0, loc) if b.uint8() != opPlusUconst { err = DecodeError{name, kid.Offset, "unexpected opcode"} goto Error } f.ByteOffset = int64(b.uint()) if b.err != nil { err = b.err goto Error } case int64: f.ByteOffset = loc } f.Name, _ = kid.Val(AttrName).(string) f.ByteSize, _ = kid.Val(AttrByteSize).(int64) haveBitOffset := false haveDataBitOffset := false f.BitOffset, haveBitOffset = kid.Val(AttrBitOffset).(int64) f.DataBitOffset, haveDataBitOffset = kid.Val(AttrDataBitOffset).(int64) if haveBitOffset && haveDataBitOffset { err = DecodeError{name, e.Offset, "duplicate bit offset attributes"} goto Error } f.BitSize, _ = kid.Val(AttrBitSize).(int64) t.Field = append(t.Field, f) if lastFieldBitSize == 0 && lastFieldByteOffset == f.ByteOffset && t.Kind != "union" { // Last field was zero width. Fix array length. // (DWARF writes out 0-length arrays as if they were 1-length arrays.) fixups.recordArrayType(lastFieldType) } lastFieldType = &f.Type lastFieldByteOffset = f.ByteOffset lastFieldBitSize = f.BitSize } if t.Kind != "union" { b, ok := e.Val(AttrByteSize).(int64) if ok && b == lastFieldByteOffset { // Final field must be zero width. Fix array length. fixups.recordArrayType(lastFieldType) } } case TagConstType, TagVolatileType, TagRestrictType: // Type modifier (DWARF v2 §5.2) // Attributes: // AttrType: subtype t := new(QualType) typ = t typeCache[off] = t if t.Type = typeOf(e); err != nil { goto Error } switch e.Tag { case TagConstType: t.Qual = "const" case TagRestrictType: t.Qual = "restrict" case TagVolatileType: t.Qual = "volatile" } case TagEnumerationType: // Enumeration type (DWARF v2 §5.6) // Attributes: // AttrName: enum name if any // AttrByteSize: bytes required to represent largest value // Children: // TagEnumerator: // AttrName: name of constant // AttrConstValue: value of constant t := new(EnumType) typ = t typeCache[off] = t t.EnumName, _ = e.Val(AttrName).(string) t.Val = make([]*EnumValue, 0, 8) for kid := next(); kid != nil; kid = next() { if kid.Tag == TagEnumerator { f := new(EnumValue) f.Name, _ = kid.Val(AttrName).(string) f.Val, _ = kid.Val(AttrConstValue).(int64) n := len(t.Val) if n >= cap(t.Val) { val := make([]*EnumValue, n, n*2) copy(val, t.Val) t.Val = val } t.Val = t.Val[0 : n+1] t.Val[n] = f } } case TagPointerType: // Type modifier (DWARF v2 §5.2) // Attributes: // AttrType: subtype [not required! void* has no AttrType] // AttrAddrClass: address class [ignored] t := new(PtrType) typ = t typeCache[off] = t if e.Val(AttrType) == nil { t.Type = &VoidType{} break } t.Type = typeOf(e) case TagSubroutineType: // Subroutine type. (DWARF v2 §5.7) // Attributes: // AttrType: type of return value if any // AttrName: possible name of type [ignored] // AttrPrototyped: whether used ANSI C prototype [ignored] // Children: // TagFormalParameter: typed parameter // AttrType: type of parameter // TagUnspecifiedParameter: final ... t := new(FuncType) typ = t typeCache[off] = t if t.ReturnType = typeOf(e); err != nil { goto Error } t.ParamType = make([]Type, 0, 8) for kid := next(); kid != nil; kid = next() { var tkid Type switch kid.Tag { default: continue case TagFormalParameter: if tkid = typeOf(kid); err != nil { goto Error } case TagUnspecifiedParameters: tkid = &DotDotDotType{} } t.ParamType = append(t.ParamType, tkid) } case TagTypedef: // Typedef (DWARF v2 §5.3) // Attributes: // AttrName: name [required] // AttrType: type definition [required] t := new(TypedefType) typ = t typeCache[off] = t t.Name, _ = e.Val(AttrName).(string) t.Type = typeOf(e) case TagUnspecifiedType: // Unspecified type (DWARF v3 §5.2) // Attributes: // AttrName: name t := new(UnspecifiedType) typ = t typeCache[off] = t t.Name, _ = e.Val(AttrName).(string) default: // This is some other type DIE that we're currently not // equipped to handle. Return an abstract "unsupported type" // object in such cases. t := new(UnsupportedType) typ = t typeCache[off] = t t.Tag = e.Tag t.Name, _ = e.Val(AttrName).(string) } if err != nil { goto Error } { b, ok := e.Val(AttrByteSize).(int64) if !ok { b = -1 switch t := typ.(type) { case *TypedefType: // Record that we need to resolve this // type's size once the type graph is // constructed. fixups.typedefs = append(fixups.typedefs, t) case *PtrType: b = int64(addressSize) } } typ.Common().ByteSize = b } return typ, nil Error: // If the parse fails, take the type out of the cache // so that the next call with this offset doesn't hit // the cache and return success. delete(typeCache, off) return nil, err } func zeroArray(t *Type) { at := (*t).(*ArrayType) if at.Type.Size() == 0 { return } // Make a copy to avoid invalidating typeCache. tt := *at tt.Count = 0 *t = &tt }