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go-ethereum-modded-tocallarg/accounts/abi/abigen/bind.go
jwasinger 64bd21393e
cmd/abigen, accounts/abi/bind: implement abigen version 2 (#31379) 
This PR implements a new version of the abigen utility (v2) which exists
along with the pre-existing v1 version.

Abigen is a utility command provided by go-ethereum that, given a
solidity contract ABI definition, will generate Go code to transact/call
the contract methods, converting the method parameters/results and
structures defined in the contract into corresponding Go types. This is
useful for preventing the need to write custom boilerplate code for
contract interactions.

Methods in the generated bindings perform encoding between Go types and
Solidity ABI-encoded packed bytecode, as well as some action (e.g.
`eth_call` or creating and submitting a transaction). This limits the
flexibility of how the generated bindings can be used, and prevents
easily adding new functionality, as it will make the generated bindings
larger for each feature added.

Abigen v2 was conceived of by the observation that the only
functionality that generated Go bindings ought to perform is conversion
between Go types and ABI-encoded packed data. Go-ethereum already
provides various APIs which in conjunction with conversion methods
generated in v2 bindings can cover all functionality currently provided
by v1, and facilitate all other previously-desired use-cases.

## Generating Bindings

To generate contract bindings using abigen v2, invoke the `abigen`
command with the `--v2` flag. The functionality of all other flags is
preserved between the v2 and v1 versions.

## What is Generated in the Bindings

The execution of `abigen --v2` generates Go code containing methods
which convert between Go types and corresponding ABI-encoded data
expected by the contract. For each input-accepting contract method and
the constructor, a "packing" method is generated in the binding which
converts from Go types to the corresponding packed solidity expected by
the contract. If a method returns output, an "unpacking" method is
generated to convert this output from ABI-encoded data to the
corresponding Go types.

For contracts which emit events, an unpacking method is defined for each
event to unpack the corresponding raw log to the Go type that it
represents.

Likewise, where custom errors are defined by contracts, an unpack method
is generated to unpack raw error data into a Go type.

## Using the Generated Bindings

For a smooth user-experience, abigen v2 comes with a number of utility
functions to be used in conjunction with the generated bindings for
performing common contract interaction use-cases. These include:

* filtering for historical logs of a given topic
* watching the chain for emission of logs with a given topic
* contract deployment methods
* Call/Transact methods

https://geth.ethereum.org will be updated to include a new tutorial page
for abigen v2 with full code examples. The page currently exists in a
PR: https://github.com/ethereum/go-ethereum/pull/31390 .

There are also extensive examples of interactions with contract bindings
in [test
cases](cc855c7ede/accounts/abi/bind/v2/lib_test.go)
provided with this PR.

---------

Co-authored-by: Sina Mahmoodi <itz.s1na@gmail.com>
Co-authored-by: Felix Lange <fjl@twurst.com>
2025-03-17 15:56:55 +01:00

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// Copyright 2016 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 abigen generates Ethereum contract Go bindings.
//
// Detailed usage document and tutorial available on the go-ethereum Wiki page:
// https://geth.ethereum.org/docs/developers/dapp-developer/native-bindings
package abigen
import (
"bytes"
"fmt"
"go/format"
"regexp"
"strings"
"text/template"
"unicode"
"github.com/ethereum/go-ethereum/accounts/abi"
"github.com/ethereum/go-ethereum/log"
)
func isKeyWord(arg string) bool {
switch arg {
case "break":
case "case":
case "chan":
case "const":
case "continue":
case "default":
case "defer":
case "else":
case "fallthrough":
case "for":
case "func":
case "go":
case "goto":
case "if":
case "import":
case "interface":
case "iota":
case "map":
case "make":
case "new":
case "package":
case "range":
case "return":
case "select":
case "struct":
case "switch":
case "type":
case "var":
default:
return false
}
return true
}
// Bind generates a Go wrapper around a contract ABI. This wrapper isn't meant
// to be used as is in client code, but rather as an intermediate struct which
// enforces compile time type safety and naming convention as opposed to having to
// manually maintain hard coded strings that break on runtime.
func Bind(types []string, abis []string, bytecodes []string, fsigs []map[string]string, pkg string, libs map[string]string, aliases map[string]string) (string, error) {
var (
// contracts is the map of each individual contract requested binding
contracts = make(map[string]*tmplContract)
// structs is the map of all redeclared structs shared by passed contracts.
structs = make(map[string]*tmplStruct)
// isLib is the map used to flag each encountered library as such
isLib = make(map[string]struct{})
)
for i := 0; i < len(types); i++ {
// Parse the actual ABI to generate the binding for
evmABI, err := abi.JSON(strings.NewReader(abis[i]))
if err != nil {
return "", err
}
// Strip any whitespace from the JSON ABI
strippedABI := strings.Map(func(r rune) rune {
if unicode.IsSpace(r) {
return -1
}
return r
}, abis[i])
// Extract the call and transact methods; events, struct definitions; and sort them alphabetically
var (
calls = make(map[string]*tmplMethod)
transacts = make(map[string]*tmplMethod)
events = make(map[string]*tmplEvent)
fallback *tmplMethod
receive *tmplMethod
// identifiers are used to detect duplicated identifiers of functions
// and events. For all calls, transacts and events, abigen will generate
// corresponding bindings. However we have to ensure there is no
// identifier collisions in the bindings of these categories.
callIdentifiers = make(map[string]bool)
transactIdentifiers = make(map[string]bool)
eventIdentifiers = make(map[string]bool)
)
for _, input := range evmABI.Constructor.Inputs {
if hasStruct(input.Type) {
bindStructType(input.Type, structs)
}
}
for _, original := range evmABI.Methods {
// Normalize the method for capital cases and non-anonymous inputs/outputs
normalized := original
normalizedName := abi.ToCamelCase(alias(aliases, original.Name))
// Ensure there is no duplicated identifier
var identifiers = callIdentifiers
if !original.IsConstant() {
identifiers = transactIdentifiers
}
// Name shouldn't start with a digit. It will make the generated code invalid.
if len(normalizedName) > 0 && unicode.IsDigit(rune(normalizedName[0])) {
normalizedName = fmt.Sprintf("M%s", normalizedName)
normalizedName = abi.ResolveNameConflict(normalizedName, func(name string) bool {
_, ok := identifiers[name]
return ok
})
}
if identifiers[normalizedName] {
return "", fmt.Errorf("duplicated identifier \"%s\"(normalized \"%s\"), use --alias for renaming", original.Name, normalizedName)
}
identifiers[normalizedName] = true
normalized.Name = normalizedName
normalized.Inputs = make([]abi.Argument, len(original.Inputs))
copy(normalized.Inputs, original.Inputs)
for j, input := range normalized.Inputs {
if input.Name == "" || isKeyWord(input.Name) {
normalized.Inputs[j].Name = fmt.Sprintf("arg%d", j)
}
if hasStruct(input.Type) {
bindStructType(input.Type, structs)
}
}
normalized.Outputs = make([]abi.Argument, len(original.Outputs))
copy(normalized.Outputs, original.Outputs)
for j, output := range normalized.Outputs {
if output.Name != "" {
normalized.Outputs[j].Name = abi.ToCamelCase(output.Name)
}
if hasStruct(output.Type) {
bindStructType(output.Type, structs)
}
}
// Append the methods to the call or transact lists
if original.IsConstant() {
calls[original.Name] = &tmplMethod{Original: original, Normalized: normalized, Structured: structured(original.Outputs)}
} else {
transacts[original.Name] = &tmplMethod{Original: original, Normalized: normalized, Structured: structured(original.Outputs)}
}
}
for _, original := range evmABI.Events {
// Skip anonymous events as they don't support explicit filtering
if original.Anonymous {
continue
}
// Normalize the event for capital cases and non-anonymous outputs
normalized := original
// Ensure there is no duplicated identifier
normalizedName := abi.ToCamelCase(alias(aliases, original.Name))
// Name shouldn't start with a digit. It will make the generated code invalid.
if len(normalizedName) > 0 && unicode.IsDigit(rune(normalizedName[0])) {
normalizedName = fmt.Sprintf("E%s", normalizedName)
normalizedName = abi.ResolveNameConflict(normalizedName, func(name string) bool {
_, ok := eventIdentifiers[name]
return ok
})
}
if eventIdentifiers[normalizedName] {
return "", fmt.Errorf("duplicated identifier \"%s\"(normalized \"%s\"), use --alias for renaming", original.Name, normalizedName)
}
eventIdentifiers[normalizedName] = true
normalized.Name = normalizedName
used := make(map[string]bool)
normalized.Inputs = make([]abi.Argument, len(original.Inputs))
copy(normalized.Inputs, original.Inputs)
for j, input := range normalized.Inputs {
if input.Name == "" || isKeyWord(input.Name) {
normalized.Inputs[j].Name = fmt.Sprintf("arg%d", j)
}
// Event is a bit special, we need to define event struct in binding,
// ensure there is no camel-case-style name conflict.
for index := 0; ; index++ {
if !used[abi.ToCamelCase(normalized.Inputs[j].Name)] {
used[abi.ToCamelCase(normalized.Inputs[j].Name)] = true
break
}
normalized.Inputs[j].Name = fmt.Sprintf("%s%d", normalized.Inputs[j].Name, index)
}
if hasStruct(input.Type) {
bindStructType(input.Type, structs)
}
}
// Append the event to the accumulator list
events[original.Name] = &tmplEvent{Original: original, Normalized: normalized}
}
// Add two special fallback functions if they exist
if evmABI.HasFallback() {
fallback = &tmplMethod{Original: evmABI.Fallback}
}
if evmABI.HasReceive() {
receive = &tmplMethod{Original: evmABI.Receive}
}
contracts[types[i]] = &tmplContract{
Type: abi.ToCamelCase(types[i]),
InputABI: strings.ReplaceAll(strippedABI, "\"", "\\\""),
InputBin: strings.TrimPrefix(strings.TrimSpace(bytecodes[i]), "0x"),
Constructor: evmABI.Constructor,
Calls: calls,
Transacts: transacts,
Fallback: fallback,
Receive: receive,
Events: events,
Libraries: make(map[string]string),
}
// Function 4-byte signatures are stored in the same sequence
// as types, if available.
if len(fsigs) > i {
contracts[types[i]].FuncSigs = fsigs[i]
}
// Parse library references.
for pattern, name := range libs {
matched, err := regexp.MatchString("__\\$"+pattern+"\\$__", contracts[types[i]].InputBin)
if err != nil {
log.Error("Could not search for pattern", "pattern", pattern, "contract", contracts[types[i]], "err", err)
}
if matched {
contracts[types[i]].Libraries[pattern] = name
// keep track that this type is a library
if _, ok := isLib[name]; !ok {
isLib[name] = struct{}{}
}
}
}
}
// Check if that type has already been identified as a library
for i := 0; i < len(types); i++ {
_, ok := isLib[types[i]]
contracts[types[i]].Library = ok
}
// Generate the contract template data content and render it
data := &tmplData{
Package: pkg,
Contracts: contracts,
Libraries: libs,
Structs: structs,
}
buffer := new(bytes.Buffer)
funcs := map[string]interface{}{
"bindtype": bindType,
"bindtopictype": bindTopicType,
"capitalise": abi.ToCamelCase,
"decapitalise": decapitalise,
}
tmpl := template.Must(template.New("").Funcs(funcs).Parse(tmplSource))
if err := tmpl.Execute(buffer, data); err != nil {
return "", err
}
// Pass the code through gofmt to clean it up
code, err := format.Source(buffer.Bytes())
if err != nil {
return "", fmt.Errorf("%v\n%s", err, buffer)
}
return string(code), nil
}
// bindBasicType converts basic solidity types(except array, slice and tuple) to Go ones.
func bindBasicType(kind abi.Type) string {
switch kind.T {
case abi.AddressTy:
return "common.Address"
case abi.IntTy, abi.UintTy:
parts := regexp.MustCompile(`(u)?int([0-9]*)`).FindStringSubmatch(kind.String())
switch parts[2] {
case "8", "16", "32", "64":
return fmt.Sprintf("%sint%s", parts[1], parts[2])
}
return "*big.Int"
case abi.FixedBytesTy:
return fmt.Sprintf("[%d]byte", kind.Size)
case abi.BytesTy:
return "[]byte"
case abi.FunctionTy:
return "[24]byte"
default:
// string, bool types
return kind.String()
}
}
// bindType converts solidity types to Go ones. Since there is no clear mapping
// from all Solidity types to Go ones (e.g. uint17), those that cannot be exactly
// mapped will use an upscaled type (e.g. BigDecimal).
func bindType(kind abi.Type, structs map[string]*tmplStruct) string {
switch kind.T {
case abi.TupleTy:
return structs[kind.TupleRawName+kind.String()].Name
case abi.ArrayTy:
return fmt.Sprintf("[%d]", kind.Size) + bindType(*kind.Elem, structs)
case abi.SliceTy:
return "[]" + bindType(*kind.Elem, structs)
default:
return bindBasicType(kind)
}
}
// bindTopicType converts a Solidity topic type to a Go one. It is almost the same
// functionality as for simple types, but dynamic types get converted to hashes.
func bindTopicType(kind abi.Type, structs map[string]*tmplStruct) string {
bound := bindType(kind, structs)
// todo(rjl493456442) according solidity documentation, indexed event
// parameters that are not value types i.e. arrays and structs are not
// stored directly but instead a keccak256-hash of an encoding is stored.
//
// We only convert strings and bytes to hash, still need to deal with
// array(both fixed-size and dynamic-size) and struct.
if bound == "string" || bound == "[]byte" {
bound = "common.Hash"
}
return bound
}
// bindStructType converts a Solidity tuple type to a Go one and records the mapping
// in the given map. Notably, this function will resolve and record nested struct
// recursively.
func bindStructType(kind abi.Type, structs map[string]*tmplStruct) string {
switch kind.T {
case abi.TupleTy:
// We compose a raw struct name and a canonical parameter expression
// together here. The reason is before solidity v0.5.11, kind.TupleRawName
// is empty, so we use canonical parameter expression to distinguish
// different struct definition. From the consideration of backward
// compatibility, we concat these two together so that if kind.TupleRawName
// is not empty, it can have unique id.
id := kind.TupleRawName + kind.String()
if s, exist := structs[id]; exist {
return s.Name
}
var (
names = make(map[string]bool)
fields []*tmplField
)
for i, elem := range kind.TupleElems {
name := abi.ToCamelCase(kind.TupleRawNames[i])
name = abi.ResolveNameConflict(name, func(s string) bool { return names[s] })
names[name] = true
fields = append(fields, &tmplField{
Type: bindStructType(*elem, structs),
Name: name,
SolKind: *elem,
})
}
name := kind.TupleRawName
if name == "" {
name = fmt.Sprintf("Struct%d", len(structs))
}
name = abi.ToCamelCase(name)
structs[id] = &tmplStruct{
Name: name,
Fields: fields,
}
return name
case abi.ArrayTy:
return fmt.Sprintf("[%d]", kind.Size) + bindStructType(*kind.Elem, structs)
case abi.SliceTy:
return "[]" + bindStructType(*kind.Elem, structs)
default:
return bindBasicType(kind)
}
}
// alias returns an alias of the given string based on the aliasing rules
// or returns itself if no rule is matched.
func alias(aliases map[string]string, n string) string {
if alias, exist := aliases[n]; exist {
return alias
}
return n
}
// decapitalise makes a camel-case string which starts with a lower case character.
func decapitalise(input string) string {
if len(input) == 0 {
return input
}
goForm := abi.ToCamelCase(input)
return strings.ToLower(goForm[:1]) + goForm[1:]
}
// structured checks whether a list of ABI data types has enough information to
// operate through a proper Go struct or if flat returns are needed.
func structured(args abi.Arguments) bool {
if len(args) < 2 {
return false
}
exists := make(map[string]bool)
for _, out := range args {
// If the name is anonymous, we can't organize into a struct
if out.Name == "" {
return false
}
// If the field name is empty when normalized or collides (var, Var, _var, _Var),
// we can't organize into a struct
field := abi.ToCamelCase(out.Name)
if field == "" || exists[field] {
return false
}
exists[field] = true
}
return true
}
// hasStruct returns an indicator whether the given type is struct, struct slice
// or struct array.
func hasStruct(t abi.Type) bool {
switch t.T {
case abi.SliceTy:
return hasStruct(*t.Elem)
case abi.ArrayTy:
return hasStruct(*t.Elem)
case abi.TupleTy:
return true
default:
return false
}
}
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