plugeth/accounts/abi/type.go
gary rong 44b74cfc40 accounts/abi: add internalType information and fix issues (#20179)
* accounts/abi: fix various issues

The fixed issues include:

(1) If there is no return in a call function, unpack should
return nil error

(2) For some functions which have struct array as parameter,
it will also be detected and generate the struct definition

(3) For event, if it has non-indexed parameter, the parameter
name will also be assigned if empty. Also the internal struct
will be detected and generate struct defition if not exist.

(4) Fix annotation generation in event function

* accounts/abi: add new abi field internalType

* accounts: address comments and add tests

* accounts/abi: replace strings.ReplaceAll with strings.Replace
2019-10-31 14:17:51 +01:00

366 lines
10 KiB
Go

// Copyright 2015 The go-ethereum Authors
// This file is part of the go-ethereum library.
//
// The go-ethereum library is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// The go-ethereum library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
package abi
import (
"errors"
"fmt"
"reflect"
"regexp"
"strconv"
"strings"
)
// Type enumerator
const (
IntTy byte = iota
UintTy
BoolTy
StringTy
SliceTy
ArrayTy
TupleTy
AddressTy
FixedBytesTy
BytesTy
HashTy
FixedPointTy
FunctionTy
)
// Type is the reflection of the supported argument type
type Type struct {
Elem *Type
Kind reflect.Kind
Type reflect.Type
Size int
T byte // Our own type checking
stringKind string // holds the unparsed string for deriving signatures
// Tuple relative fields
TupleRawName string // Raw struct name defined in source code, may be empty.
TupleElems []*Type // Type information of all tuple fields
TupleRawNames []string // Raw field name of all tuple fields
}
var (
// typeRegex parses the abi sub types
typeRegex = regexp.MustCompile("([a-zA-Z]+)(([0-9]+)(x([0-9]+))?)?")
)
// NewType creates a new reflection type of abi type given in t.
func NewType(t string, internalType string, components []ArgumentMarshaling) (typ Type, err error) {
// check that array brackets are equal if they exist
if strings.Count(t, "[") != strings.Count(t, "]") {
return Type{}, fmt.Errorf("invalid arg type in abi")
}
typ.stringKind = t
// if there are brackets, get ready to go into slice/array mode and
// recursively create the type
if strings.Count(t, "[") != 0 {
// Note internalType can be empty here.
subInternal := internalType
if i := strings.LastIndex(internalType, "["); i != -1 {
subInternal = subInternal[:i]
}
// recursively embed the type
i := strings.LastIndex(t, "[")
embeddedType, err := NewType(t[:i], subInternal, components)
if err != nil {
return Type{}, err
}
// grab the last cell and create a type from there
sliced := t[i:]
// grab the slice size with regexp
re := regexp.MustCompile("[0-9]+")
intz := re.FindAllString(sliced, -1)
if len(intz) == 0 {
// is a slice
typ.T = SliceTy
typ.Kind = reflect.Slice
typ.Elem = &embeddedType
typ.Type = reflect.SliceOf(embeddedType.Type)
typ.stringKind = embeddedType.stringKind + sliced
} else if len(intz) == 1 {
// is a array
typ.T = ArrayTy
typ.Kind = reflect.Array
typ.Elem = &embeddedType
typ.Size, err = strconv.Atoi(intz[0])
if err != nil {
return Type{}, fmt.Errorf("abi: error parsing variable size: %v", err)
}
typ.Type = reflect.ArrayOf(typ.Size, embeddedType.Type)
typ.stringKind = embeddedType.stringKind + sliced
} else {
return Type{}, fmt.Errorf("invalid formatting of array type")
}
return typ, err
}
// parse the type and size of the abi-type.
matches := typeRegex.FindAllStringSubmatch(t, -1)
if len(matches) == 0 {
return Type{}, fmt.Errorf("invalid type '%v'", t)
}
parsedType := matches[0]
// varSize is the size of the variable
var varSize int
if len(parsedType[3]) > 0 {
var err error
varSize, err = strconv.Atoi(parsedType[2])
if err != nil {
return Type{}, fmt.Errorf("abi: error parsing variable size: %v", err)
}
} else {
if parsedType[0] == "uint" || parsedType[0] == "int" {
// this should fail because it means that there's something wrong with
// the abi type (the compiler should always format it to the size...always)
return Type{}, fmt.Errorf("unsupported arg type: %s", t)
}
}
// varType is the parsed abi type
switch varType := parsedType[1]; varType {
case "int":
typ.Kind, typ.Type = reflectIntKindAndType(false, varSize)
typ.Size = varSize
typ.T = IntTy
case "uint":
typ.Kind, typ.Type = reflectIntKindAndType(true, varSize)
typ.Size = varSize
typ.T = UintTy
case "bool":
typ.Kind = reflect.Bool
typ.T = BoolTy
typ.Type = reflect.TypeOf(bool(false))
case "address":
typ.Kind = reflect.Array
typ.Type = addressT
typ.Size = 20
typ.T = AddressTy
case "string":
typ.Kind = reflect.String
typ.Type = reflect.TypeOf("")
typ.T = StringTy
case "bytes":
if varSize == 0 {
typ.T = BytesTy
typ.Kind = reflect.Slice
typ.Type = reflect.SliceOf(reflect.TypeOf(byte(0)))
} else {
typ.T = FixedBytesTy
typ.Kind = reflect.Array
typ.Size = varSize
typ.Type = reflect.ArrayOf(varSize, reflect.TypeOf(byte(0)))
}
case "tuple":
var (
fields []reflect.StructField
elems []*Type
names []string
expression string // canonical parameter expression
)
expression += "("
for idx, c := range components {
cType, err := NewType(c.Type, c.InternalType, c.Components)
if err != nil {
return Type{}, err
}
if ToCamelCase(c.Name) == "" {
return Type{}, errors.New("abi: purely anonymous or underscored field is not supported")
}
fields = append(fields, reflect.StructField{
Name: ToCamelCase(c.Name), // reflect.StructOf will panic for any exported field.
Type: cType.Type,
Tag: reflect.StructTag("json:\"" + c.Name + "\""),
})
elems = append(elems, &cType)
names = append(names, c.Name)
expression += cType.stringKind
if idx != len(components)-1 {
expression += ","
}
}
expression += ")"
typ.Kind = reflect.Struct
typ.Type = reflect.StructOf(fields)
typ.TupleElems = elems
typ.TupleRawNames = names
typ.T = TupleTy
typ.stringKind = expression
const structPrefix = "struct "
// After solidity 0.5.10, a new field of abi "internalType"
// is introduced. From that we can obtain the struct name
// user defined in the source code.
if internalType != "" && strings.HasPrefix(internalType, structPrefix) {
// Foo.Bar type definition is not allowed in golang,
// convert the format to FooBar
typ.TupleRawName = strings.Replace(internalType[len(structPrefix):], ".", "", -1)
}
case "function":
typ.Kind = reflect.Array
typ.T = FunctionTy
typ.Size = 24
typ.Type = reflect.ArrayOf(24, reflect.TypeOf(byte(0)))
default:
return Type{}, fmt.Errorf("unsupported arg type: %s", t)
}
return
}
// String implements Stringer
func (t Type) String() (out string) {
return t.stringKind
}
func (t Type) pack(v reflect.Value) ([]byte, error) {
// dereference pointer first if it's a pointer
v = indirect(v)
if err := typeCheck(t, v); err != nil {
return nil, err
}
switch t.T {
case SliceTy, ArrayTy:
var ret []byte
if t.requiresLengthPrefix() {
// append length
ret = append(ret, packNum(reflect.ValueOf(v.Len()))...)
}
// calculate offset if any
offset := 0
offsetReq := isDynamicType(*t.Elem)
if offsetReq {
offset = getTypeSize(*t.Elem) * v.Len()
}
var tail []byte
for i := 0; i < v.Len(); i++ {
val, err := t.Elem.pack(v.Index(i))
if err != nil {
return nil, err
}
if !offsetReq {
ret = append(ret, val...)
continue
}
ret = append(ret, packNum(reflect.ValueOf(offset))...)
offset += len(val)
tail = append(tail, val...)
}
return append(ret, tail...), nil
case TupleTy:
// (T1,...,Tk) for k >= 0 and any types T1, …, Tk
// enc(X) = head(X(1)) ... head(X(k)) tail(X(1)) ... tail(X(k))
// where X = (X(1), ..., X(k)) and head and tail are defined for Ti being a static
// type as
// head(X(i)) = enc(X(i)) and tail(X(i)) = "" (the empty string)
// and as
// head(X(i)) = enc(len(head(X(1)) ... head(X(k)) tail(X(1)) ... tail(X(i-1))))
// tail(X(i)) = enc(X(i))
// otherwise, i.e. if Ti is a dynamic type.
fieldmap, err := mapArgNamesToStructFields(t.TupleRawNames, v)
if err != nil {
return nil, err
}
// Calculate prefix occupied size.
offset := 0
for _, elem := range t.TupleElems {
offset += getTypeSize(*elem)
}
var ret, tail []byte
for i, elem := range t.TupleElems {
field := v.FieldByName(fieldmap[t.TupleRawNames[i]])
if !field.IsValid() {
return nil, fmt.Errorf("field %s for tuple not found in the given struct", t.TupleRawNames[i])
}
val, err := elem.pack(field)
if err != nil {
return nil, err
}
if isDynamicType(*elem) {
ret = append(ret, packNum(reflect.ValueOf(offset))...)
tail = append(tail, val...)
offset += len(val)
} else {
ret = append(ret, val...)
}
}
return append(ret, tail...), nil
default:
return packElement(t, v), nil
}
}
// requireLengthPrefix returns whether the type requires any sort of length
// prefixing.
func (t Type) requiresLengthPrefix() bool {
return t.T == StringTy || t.T == BytesTy || t.T == SliceTy
}
// isDynamicType returns true if the type is dynamic.
// The following types are called “dynamic”:
// * bytes
// * string
// * T[] for any T
// * T[k] for any dynamic T and any k >= 0
// * (T1,...,Tk) if Ti is dynamic for some 1 <= i <= k
func isDynamicType(t Type) bool {
if t.T == TupleTy {
for _, elem := range t.TupleElems {
if isDynamicType(*elem) {
return true
}
}
return false
}
return t.T == StringTy || t.T == BytesTy || t.T == SliceTy || (t.T == ArrayTy && isDynamicType(*t.Elem))
}
// getTypeSize returns the size that this type needs to occupy.
// We distinguish static and dynamic types. Static types are encoded in-place
// and dynamic types are encoded at a separately allocated location after the
// current block.
// So for a static variable, the size returned represents the size that the
// variable actually occupies.
// For a dynamic variable, the returned size is fixed 32 bytes, which is used
// to store the location reference for actual value storage.
func getTypeSize(t Type) int {
if t.T == ArrayTy && !isDynamicType(*t.Elem) {
// Recursively calculate type size if it is a nested array
if t.Elem.T == ArrayTy {
return t.Size * getTypeSize(*t.Elem)
}
return t.Size * 32
} else if t.T == TupleTy && !isDynamicType(t) {
total := 0
for _, elem := range t.TupleElems {
total += getTypeSize(*elem)
}
return total
}
return 32
}