neo-go/pkg/compiler/compiler.go

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package compiler
import (
"encoding/json"
"errors"
"fmt"
"go/ast"
"go/parser"
"go/token"
"go/types"
"io"
"os"
"path/filepath"
"sort"
"strings"
"github.com/nspcc-dev/neo-go/pkg/smartcontract"
"github.com/nspcc-dev/neo-go/pkg/smartcontract/binding"
"github.com/nspcc-dev/neo-go/pkg/smartcontract/manifest"
"github.com/nspcc-dev/neo-go/pkg/smartcontract/manifest/standard"
"github.com/nspcc-dev/neo-go/pkg/smartcontract/nef"
"github.com/nspcc-dev/neo-go/pkg/smartcontract/rpcbinding"
"github.com/nspcc-dev/neo-go/pkg/util"
"golang.org/x/tools/go/packages"
"gopkg.in/yaml.v3"
)
const fileExt = "nef"
// Options contains all the parameters that affect the behavior of the compiler.
type Options struct {
// The extension of the output file default set to .nef
Ext string
// The name of the output file.
Outfile string
// The name of the output for debug info.
DebugInfo string
// The name of the output for contract manifest file.
ManifestFile string
// NoEventsCheck specifies if events emitted by contract needs to be present in manifest.
// This setting has effect only if manifest is emitted.
NoEventsCheck bool
// NoStandardCheck specifies if supported standards compliance needs to be checked.
// This setting has effect only if manifest is emitted.
NoStandardCheck bool
// NoPermissionsCheck specifies if permissions in YAML config need to be checked
// against invocations performed by the contract.
// This setting has effect only if manifest is emitted.
NoPermissionsCheck bool
// GuessEventTypes specifies if types of runtime notifications need to be guessed
// from the usage context. These types are used for RPC binding generation only and
// can be defined for events with name known at the compilation time and without
// variadic args usages. If some type is specified via config file, then the config's
// one is preferable. Currently, event's parameter type is defined from the first
// occurrence of event call.
GuessEventTypes bool
// Name is a contract's name to be written to manifest.
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Name string
// SourceURL is a contract's source URL to be written to manifest.
SourceURL string
// Runtime notifications declared in the contract configuration file.
ContractEvents []HybridEvent
// DeclaredNamedTypes is the set of named types that were declared in the
// contract configuration type and are the part of manifest events.
DeclaredNamedTypes map[string]binding.ExtendedType
// The list of standards supported by the contract.
ContractSupportedStandards []string
// SafeMethods contains a list of methods which will be marked as safe in manifest.
SafeMethods []string
// Overloads contains mapping from the compiled method name to the name emitted in manifest.
// It can be used to provide method overloads as Go doesn't have such capability.
Overloads map[string]string
// Permissions is a list of permissions for every contract method.
Permissions []manifest.Permission
// BindingsFile contains configuration for smart-contract bindings generator.
BindingsFile string
}
// HybridEvent represents the description of event emitted by the contract squashed
// with extended event's parameters description. We have it as a separate type for
// the user's convenience. It is applied for the smart contract configuration file
// only.
type HybridEvent struct {
Name string `json:"name"`
Parameters []HybridParameter `json:"parameters"`
}
// HybridParameter contains the manifest's event parameter description united with
// the extended type description for this parameter. It is applied for the smart
// contract configuration file only.
type HybridParameter struct {
manifest.Parameter `yaml:",inline"`
ExtendedType *binding.ExtendedType `yaml:"extendedtype,omitempty"`
}
type buildInfo struct {
config *packages.Config
program []*packages.Package
options *Options
}
// ForEachPackage executes fn on each package used in the current program
// in the order they should be initialized.
func (c *codegen) ForEachPackage(fn func(*packages.Package)) {
for _, pkgPath := range c.packages {
p := c.packageCache[pkgPath]
c.typeInfo = p.TypesInfo
c.currPkg = p
fn(p)
}
}
// ForEachFile executes fn on each file used in the current program.
func (c *codegen) ForEachFile(fn func(*ast.File, *types.Package)) {
c.ForEachPackage(func(pkg *packages.Package) {
for _, f := range pkg.Syntax {
c.fillImportMap(f, pkg)
fn(f, pkg.Types)
}
})
}
// fillImportMap fills import map for f.
func (c *codegen) fillImportMap(f *ast.File, pkg *packages.Package) {
c.importMap = map[string]string{"": pkg.PkgPath}
for _, imp := range f.Imports {
// We need to load find package metadata because
// name specified in `package ...` decl, can be in
// conflict with package path.
pkgPath := strings.Trim(imp.Path.Value, `"`)
realPkg := pkg.Imports[pkgPath]
name := realPkg.Name
if imp.Name != nil {
name = imp.Name.Name
}
c.importMap[name] = realPkg.PkgPath
}
}
func getBuildInfo(name string, src any) (*buildInfo, error) {
dir, err := filepath.Abs(name)
if err != nil {
return nil, err
}
absName := dir
singleFile := strings.HasSuffix(absName, ".go")
if singleFile {
dir = filepath.Dir(dir)
}
conf := &packages.Config{
Mode: packages.NeedName |
packages.NeedImports |
packages.NeedDeps |
packages.NeedTypes |
packages.NeedSyntax |
packages.NeedTypesInfo,
Fset: token.NewFileSet(),
Dir: dir,
Overlay: make(map[string][]byte),
}
var names []string
if src != nil {
var buf []byte
var err error
switch s := src.(type) {
case string:
buf = []byte(s)
case io.Reader:
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buf, err = io.ReadAll(s)
if err != nil {
return nil, err
}
default:
panic(fmt.Sprintf("unsupported src type: %T", s))
}
names = append(names, name)
conf.Overlay[absName] = buf
} else {
if strings.HasSuffix(name, ".go") {
names = append(names, "file="+absName)
} else {
names = append(names, "pattern="+absName)
}
}
conf.ParseFile = func(fset *token.FileSet, filename string, src []byte) (*ast.File, error) {
// When compiling a single file we can or can not load other files from the same package.
// Here we chose the latter which is consistent with `go run` behavior.
// Other dependencies should still be processed.
if singleFile && filepath.Dir(filename) == filepath.Dir(absName) && filename != absName {
return nil, nil
}
const mode = parser.AllErrors
return parser.ParseFile(fset, filename, src, mode)
}
prog, err := packages.Load(conf, names...)
if err != nil {
return nil, err
}
for _, p := range prog {
if len(p.Errors) != 0 {
return nil, p.Errors[0]
}
}
return &buildInfo{
config: conf,
program: prog,
}, nil
}
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// Compile compiles a Go program into a bytecode that can run on the Neo virtual machine.
// If `r != nil`, `name` is interpreted as a filename, and `r` as file contents.
// Otherwise `name` is either a file name or a name of the directory containing source files.
func Compile(name string, r io.Reader) ([]byte, error) {
f, _, err := CompileWithOptions(name, r, nil)
if err != nil {
return nil, err
}
return f.Script, nil
}
// CompileWithOptions compiles a Go program into bytecode with the provided compiler options.
func CompileWithOptions(name string, r io.Reader, o *Options) (*nef.File, *DebugInfo, error) {
ctx, err := getBuildInfo(name, r)
if err != nil {
return nil, nil, err
}
ctx.options = o
return codeGen(ctx)
}
// CompileAndSave will compile and save the file to disk in the NEF format.
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func CompileAndSave(src string, o *Options) ([]byte, error) {
o.Outfile = strings.TrimSuffix(o.Outfile, fmt.Sprintf(".%s", fileExt))
if len(o.Outfile) == 0 {
if strings.HasSuffix(src, ".go") {
o.Outfile = strings.TrimSuffix(src, ".go")
} else {
o.Outfile = "out"
}
}
if len(o.Ext) == 0 {
o.Ext = fileExt
}
f, di, err := CompileWithOptions(src, nil, o)
if err != nil {
return nil, fmt.Errorf("error while trying to compile smart contract file: %w", err)
}
if o.SourceURL != "" {
if len(o.SourceURL) > nef.MaxSourceURLLength {
return nil, errors.New("too long source URL")
}
f.Source = o.SourceURL
f.Checksum = f.CalculateChecksum()
}
bytes, err := f.Bytes()
if err != nil {
return nil, fmt.Errorf("error while serializing .nef file: %w", err)
}
out := fmt.Sprintf("%s.%s", o.Outfile, o.Ext)
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err = os.WriteFile(out, bytes, os.ModePerm)
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if err != nil {
return f.Script, err
}
if o.DebugInfo == "" && o.ManifestFile == "" && o.BindingsFile == "" {
return f.Script, nil
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}
if o.DebugInfo != "" {
di.Events = make([]EventDebugInfo, len(o.ContractEvents))
for i, e := range o.ContractEvents {
params := make([]DebugParam, len(e.Parameters))
for j, p := range e.Parameters {
params[j] = DebugParam{
Name: p.Name,
Type: p.Type.String(),
}
}
di.Events[i] = EventDebugInfo{
ID: e.Name,
// DebugInfo event name should be at the format {namespace},{name}
// but we don't provide namespace via .yml config
Name: "," + e.Name,
Parameters: params,
}
}
data, err := json.Marshal(di)
if err != nil {
return f.Script, err
}
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if err := os.WriteFile(o.DebugInfo, data, os.ModePerm); err != nil {
return f.Script, err
}
}
if o.BindingsFile != "" {
cfg := binding.NewConfig()
cfg.Package = di.MainPkg
for _, m := range di.Methods {
if !m.IsExported {
continue
}
for _, p := range m.Parameters {
pname := m.Name.Name + "." + p.Name
if p.RealType.TypeName != "" {
cfg.Overrides[pname] = p.RealType
}
if p.ExtendedType != nil {
cfg.Types[pname] = *p.ExtendedType
}
}
if m.ReturnTypeReal.TypeName != "" {
cfg.Overrides[m.Name.Name] = m.ReturnTypeReal
}
if m.ReturnTypeExtended != nil {
cfg.Types[m.Name.Name] = *m.ReturnTypeExtended
}
}
if len(di.NamedTypes) > 0 {
cfg.NamedTypes = di.NamedTypes
}
for name, et := range o.DeclaredNamedTypes {
if _, ok := cfg.NamedTypes[name]; ok {
return nil, fmt.Errorf("configured declared named type intersects with the contract's one: `%s`", name)
}
cfg.NamedTypes[name] = et
}
for _, e := range o.ContractEvents {
eStructName := rpcbinding.ToEventBindingName(e.Name)
for _, p := range e.Parameters {
pStructName := rpcbinding.ToParameterBindingName(p.Name)
if p.ExtendedType != nil {
pName := eStructName + "." + pStructName
cfg.Types[pName] = *p.ExtendedType
}
}
}
if o.GuessEventTypes {
if len(di.EmittedEvents) > 0 {
var keys = make([]string, 0, len(di.EmittedEvents))
for k := range di.EmittedEvents {
keys = append(keys, k)
}
sort.Strings(keys)
for _, eventName := range keys {
var (
eventUsages = di.EmittedEvents[eventName]
manifestEvent HybridEvent
)
for _, e := range o.ContractEvents {
if e.Name == eventName {
manifestEvent = e
break
}
}
if len(manifestEvent.Name) == 0 {
return nil, fmt.Errorf("inconsistent usages of event `%s`: not declared in the contract config", eventName)
}
exampleUsage := eventUsages[0]
for _, usage := range eventUsages {
if len(usage.Params) != len(manifestEvent.Parameters) {
return nil, fmt.Errorf("inconsistent usages of event `%s` against config: number of params mismatch: %d vs %d", eventName, len(exampleUsage.Params), len(manifestEvent.Parameters))
}
for i, actual := range usage.Params {
mParam := manifestEvent.Parameters[i]
// TODO: see the TestCompile_GuessEventTypes, "SC parameter type mismatch" section,
// do we want to compare with actual.RealType? The conversion code is emitted by the
// compiler for it, so we expect the parameter to be of the proper type.
if !(mParam.Type == smartcontract.AnyType || actual.TypeSC == mParam.Type) {
return nil, fmt.Errorf("inconsistent usages of event `%s` against config: SC type of param #%d mismatch: %s vs %s", eventName, i, actual.TypeSC, mParam.Type)
}
expected := exampleUsage.Params[i]
if !actual.ExtendedType.Equals(expected.ExtendedType) {
return nil, fmt.Errorf("inconsistent usages of event `%s`: extended type of param #%d mismatch", eventName, i)
}
}
}
eBindingName := rpcbinding.ToEventBindingName(eventName)
for _, p := range exampleUsage.Params {
pBindingName := rpcbinding.ToParameterBindingName(p.Name)
pname := eBindingName + "." + pBindingName
if p.RealType.TypeName != "" {
if _, ok := cfg.Overrides[pname]; !ok {
cfg.Overrides[pname] = p.RealType
}
}
if p.ExtendedType != nil {
typeName := p.ExtendedType.Name
if extType, ok := exampleUsage.ExtTypes[typeName]; ok {
for _, ok := cfg.NamedTypes[typeName]; ok; _, ok = cfg.NamedTypes[typeName] {
typeName = typeName + "X"
}
extType.Name = typeName
p.ExtendedType.Name = typeName
cfg.NamedTypes[typeName] = extType
}
if _, ok := cfg.Types[pname]; !ok {
cfg.Types[pname] = *p.ExtendedType
}
}
}
}
}
}
data, err := yaml.Marshal(&cfg)
if err != nil {
return nil, fmt.Errorf("can't marshal bindings configuration: %w", err)
}
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err = os.WriteFile(o.BindingsFile, data, os.ModePerm)
if err != nil {
return nil, fmt.Errorf("can't write bindings configuration: %w", err)
}
}
if o.ManifestFile != "" {
m, err := CreateManifest(di, o)
if err != nil {
return f.Script, err
}
mData, err := json.Marshal(m)
if err != nil {
return f.Script, fmt.Errorf("failed to marshal manifest to JSON: %w", err)
}
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return f.Script, os.WriteFile(o.ManifestFile, mData, os.ModePerm)
}
return f.Script, nil
}
// CreateManifest creates manifest and checks that is is valid.
func CreateManifest(di *DebugInfo, o *Options) (*manifest.Manifest, error) {
m, err := di.ConvertToManifest(o)
if err != nil {
return m, fmt.Errorf("failed to convert debug info to manifest: %w", err)
}
for _, name := range o.SafeMethods {
if m.ABI.GetMethod(name, -1) == nil {
return m, fmt.Errorf("method %s is marked as safe but missing from manifest", name)
}
}
err = m.IsValid(util.Uint160{}, true) // Check as much as possible without hash.
if err != nil {
return m, fmt.Errorf("manifest is invalid: %w", err)
}
if !o.NoStandardCheck {
if err := standard.CheckABI(m, o.ContractSupportedStandards...); err != nil {
return m, err
}
if m.ABI.GetMethod(manifest.MethodOnNEP11Payment, -1) != nil {
if err := standard.CheckABI(m, manifest.NEP11Payable); err != nil {
return m, err
}
}
if m.ABI.GetMethod(manifest.MethodOnNEP17Payment, -1) != nil {
if err := standard.CheckABI(m, manifest.NEP17Payable); err != nil {
return m, err
}
}
}
if !o.NoEventsCheck {
for name := range di.EmittedEvents {
expected := m.ABI.GetEvent(name)
if expected == nil {
return nil, fmt.Errorf("event '%s' is emitted but not specified in manifest", name)
}
for _, emitted := range di.EmittedEvents[name] {
if len(emitted.Params) != len(expected.Parameters) {
return nil, fmt.Errorf("event '%s' should have %d parameters but has %d",
name, len(expected.Parameters), len(emitted.Params))
}
for j := range expected.Parameters {
if expected.Parameters[j].Type == smartcontract.AnyType {
continue
}
expectedT := expected.Parameters[j].Type
if emitted.Params[j].TypeSC != expectedT {
return nil, fmt.Errorf("event '%s' should have '%s' as type of %d parameter, "+
"got: %s", name, expectedT, j+1, emitted.Params[j].TypeSC)
}
}
}
}
}
if !o.NoPermissionsCheck {
// We can't perform full check for 2 reasons:
// 1. Contract hash may not be available at compile time.
// 2. Permission may be specified for a group of contracts by public key.
// Thus only basic checks are performed.
for h, methods := range di.InvokedContracts {
knownHash := !h.Equals(util.Uint160{})
methodLoop:
for _, m := range methods {
for _, p := range o.Permissions {
// Group or wildcard permission is ok to try.
if knownHash && p.Contract.Type == manifest.PermissionHash && !p.Contract.Hash().Equals(h) {
continue
}
if p.Methods.Contains(m) {
continue methodLoop
}
}
if knownHash {
return nil, fmt.Errorf("method '%s' of contract %s is invoked but"+
" corresponding permission is missing", m, h.StringLE())
}
return nil, fmt.Errorf("method '%s' is invoked but"+
" corresponding permission is missing", m)
}
}
}
return m, nil
}