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