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package main
import (
"flag"
"fmt"
"go/ast"
"go/parser"
"go/token"
"os"
"path/filepath"
"regexp"
"strconv"
"strings"
table "github.com/tatsushid/go-prettytable"
)
type strBoolMap map[string]bool
func (a *strBoolMap) String() string {
var res string
for k, _ := range *a {
res += k
}
return res
}
func (a *strBoolMap) Set(str string) error {
if *a == nil {
*a = make(map[string]bool)
}
s := strings.Split(str, " ")
for _, v := range s {
(*a)[v] = true
}
return nil
}
type arrFlag struct {
active bool
content []string
}
func (a *arrFlag) String() string {
return strings.Join(a.content, " ")
}
func (a *arrFlag) Set(s string) error {
a.active = true
a.content = strings.Split(s, ",")
return nil
}
// flag that groups a boolean value and a regular expression
type regexpFlag struct {
active bool
reg *regexp.Regexp
}
func (r *regexpFlag) String() string {
if r.reg != nil {
return r.reg.String()
}
return ""
}
func (r *regexpFlag) Set(s string) error {
re := regexp.MustCompile(s)
r.active = true
r.reg = re
return nil
}
var (
allowedFun = make(map[string]map[string]bool)
allowedRep = make(map[string]int)
// Flags
noArrays bool
noRelativeImports bool
noTheseArrays strBoolMap
casting bool
noFor bool
noLit regexpFlag
allowBuiltin bool
)
// pkgFunc for all the functions of a given package
type pkgFunc struct {
functions []string
path string
}
type funcImp struct {
pkg, fun string
pos token.Pos
}
// All visitors
type callVisitor struct {
Calls []string
Fset *token.FileSet
}
// Get the position of the node in the file
type locate interface {
getPos(ast.Node) string
}
type illegal struct {
T string
Name string
Pos string
}
func (i *illegal) String() string {
return i.T + " " + i.Name + " " + i.Pos
}
// Returns the smallest block containing the position pos. It can
// return nil if `pos` is not inside any ast.BlockStmt
func smallestBlock(pos token.Pos, blocks []*ast.BlockStmt) *ast.BlockStmt {
var minBlk *ast.BlockStmt
var minSize token.Pos
for _, v := range blocks {
if pos > v.Pos() && pos < v.End() {
size := v.End() - v.Pos()
if minBlk == nil || size < minSize {
minBlk = v
minSize = size
}
}
}
return minBlk
}
type data struct {
argument bool
}
func fillScope(funcDefs []*fDefInfo, scope *ast.Scope, scopes map[*ast.BlockStmt]*ast.Scope) {
for _, fun := range funcDefs {
scope.Insert(fun.obj)
for _, name := range fun.paramsFunc {
obj := ast.NewObj(ast.Fun, name)
data := data{
argument: true,
}
obj.Data = data
scopes[fun.body].Insert(obj)
}
}
}
// Create the scopes for a BlockStmt contained inside another BlockStmt
func createChildScope(block *ast.BlockStmt, l *loadVisitor, scopes map[*ast.BlockStmt]*ast.Scope) {
blocks := l.blocks
// The smalles block containing the beggining of the block
parentBlock := smallestBlock(block.Pos(), blocks)
if scopes[parentBlock] == nil {
createChildScope(parentBlock, l, scopes)
}
scopes[block] = ast.NewScope(scopes[parentBlock])
}
// Returns true `block` is contained inside another block
func isContained(block *ast.BlockStmt, blocks []*ast.BlockStmt) bool {
for _, v := range blocks {
if block == v {
continue
}
if block.Pos() > v.Pos() && block.End() < v.End() {
return true
}
}
return false
}
// Creates all the scopes in the package
func createScopes(l *loadVisitor, pkgScope *ast.Scope) map[*ast.BlockStmt]*ast.Scope {
blocks := l.blocks
scopes := make(map[*ast.BlockStmt]*ast.Scope)
if blocks == nil {
return nil
}
for _, b := range blocks {
if !isContained(b, blocks) {
scopes[b] = ast.NewScope(pkgScope)
continue
}
}
for _, b := range blocks {
if scopes[b] != nil {
continue
}
createChildScope(b, l, scopes)
}
return scopes
}
type blockVisitor struct {
fdef []*fDefInfo // All functions defined in the scope in any
// way: as a funcDecl, GenDecl or AssigmentStmt
oneBlock bool // Indicates if the visitor already encounter a
// blockStmt
}
func (b *blockVisitor) Visit(n ast.Node) ast.Visitor {
switch t := n.(type) {
case *ast.BlockStmt:
if b.oneBlock {
return nil
}
return b
case *ast.FuncDecl, *ast.GenDecl, *ast.AssignStmt:
def := funcInfo(t)
if def == nil || def.obj == nil {
return b
}
b.fdef = append(b.fdef, def)
return nil
default:
return b
}
}
type loadedSource map[string]*loadVisitor
// Returns information about the function defined in the block node
func defs(block ast.Node) []*fDefInfo {
b := &blockVisitor{}
ast.Walk(b, block)
return b.fdef
}
func loadProgram(path string, load loadedSource) error {
l := &loadVisitor{
functions: make(map[string]ast.Node),
absImports: make(map[string]*element),
relImports: make(map[string]*element),
objFunc: make(map[*ast.Object]ast.Node),
fset: token.NewFileSet(),
scopes: make(map[*ast.BlockStmt]*ast.Scope),
}
pkgs, err := parser.ParseDir(l.fset, path, nil, parser.AllErrors)
if err != nil {
return err
}
for _, pkg := range pkgs {
ast.Walk(l, pkg)
l.pkgScope = ast.NewScope(nil)
def := defs(pkg)
for _, v := range def {
l.pkgScope.Insert(v.obj)
}
l.scopes = createScopes(l, l.pkgScope)
fillScope(def, l.pkgScope, l.scopes)
for block, scope := range l.scopes {
defs := defs(block)
fillScope(defs, scope, l.scopes)
}
load[path] = l
}
for _, v := range l.relImports {
if load[v.name] == nil {
newPath, _ := filepath.Abs(path + "/" + v.name)
err = loadProgram(newPath, load)
if err != nil {
return err
}
}
}
return err
}
func smallestScopeContaining(pos token.Pos, path string, load loadedSource) *ast.Scope {
pack := load[path]
sm := smallestBlock(pos, pack.blocks)
if sm == nil {
return pack.pkgScope
}
return pack.scopes[sm]
}
func lookupDefinitionObj(el element, path string, load loadedSource) *ast.Object {
scope := smallestScopeContaining(el.pos, path, load)
for scope != nil {
obj := scope.Lookup(el.name)
if obj != nil {
return obj
}
scope = scope.Outer
}
return nil
}
type visitor struct {
fset *token.FileSet
uses []element
selections map[string][]*element
arrays []*occurrence
lits []*occurrence
fors []*occurrence
callRep map[string]int
oneTime bool
}
func (v *visitor) getPos(n ast.Node) string {
return v.fset.Position(n.Pos()).String()
}
func (v *visitor) Visit(n ast.Node) ast.Visitor {
switch t := n.(type) {
case *ast.FuncDecl, *ast.GenDecl, *ast.AssignStmt:
//Avoids analysing a declaration inside a declaration
//Since this is handle by the functions `isAllowed`
if v.oneTime {
return nil
}
v.oneTime = true
return v
case *ast.BasicLit:
if t.Kind != token.CHAR && t.Kind != token.STRING {
return nil
}
v.lits = append(v.lits, &occurrence{pos: v.getPos(n), name: t.Value})
case *ast.ArrayType:
if op, ok := t.Elt.(*ast.Ident); ok {
v.arrays = append(v.arrays, &occurrence{
name: op.Name,
pos: v.getPos(n),
})
}
case *ast.ForStmt:
v.fors = append(v.fors, &occurrence{
name: "for",
pos: v.getPos(n),
})
case *ast.CallExpr:
if fun, ok := t.Fun.(*ast.Ident); ok {
v.uses = append(v.uses, element{
name: fun.Name,
pos: fun.Pos(),
})
v.callRep[fun.Name]++
}
case *ast.SelectorExpr:
if x, ok := t.X.(*ast.Ident); ok {
v.selections[x.Name] = append(v.selections[x.Name], &element{
name: t.Sel.Name,
pos: n.Pos(),
})
v.callRep[x.Name+"."+t.Sel.Name]++
}
}
return v
}
// Returns the info structure with all the ocurrences of the element
// of the analised in the project
func isAllowed(function element, path string, load loadedSource, walked map[ast.Node]bool, info *info) bool {
if walked == nil {
walked = make(map[ast.Node]bool)
}
fdef := lookupDefinitionObj(function, path, load)
if fdef == nil && !allowedFun["builtin"]["*"] && !allowedFun["builtin"][function.name] {
info.illegals = append(info.illegals, &illegal{
T: "illegal-call",
Name: function.name,
Pos: load[path].fset.Position(function.pos).String(),
})
return false
}
if fdef == nil {
return true
}
if arg, ok := fdef.Data.(data); ok && arg.argument {
return true
}
funcNode := load[path].objFunc[fdef]
v := &visitor{
selections: make(map[string][]*element),
callRep: make(map[string]int),
fset: load[path].fset,
}
if !walked[funcNode] {
ast.Walk(v, funcNode)
info.fors = append(info.fors, v.fors...)
info.lits = append(info.lits, v.lits...)
info.arrays = append(info.arrays, v.arrays...)
for name, v := range v.callRep {
info.callRep[name] += v
}
walked[funcNode] = true
}
if v.uses == nil && v.selections == nil {
return true
}
allowed := true
for _, use := range v.uses {
allowedUse := isAllowed(use, path, load, walked, info)
if !allowedUse {
info.illegals = append(info.illegals, &illegal{
T: "illegal-call",
Name: use.name,
Pos: load[path].fset.Position(use.pos).String(),
})
}
allowed = allowedUse && allowed
}
for pck, funcNames := range v.selections {
importRelPath := load[path].relImports[pck]
for _, fun := range funcNames {
if importRelPath == nil {
absImp := load[path].absImports[pck]
if absImp != nil && !allowedFun[absImp.name][fun.name] && !allowedFun[absImp.name]["*"] {
// Add to the illegals array the import and selection
info.illegals = append(info.illegals, &illegal{
T: "illegal-access",
Name: pck + "." + fun.name,
Pos: load[path].fset.Position(fun.pos).String(),
})
allowed = false
}
continue
}
newPath, err := filepath.Abs(path + "/" + importRelPath.name)
if err != nil {
panic(err)
}
newEl := element{
name: fun.name,
pos: token.Pos(0),
}
allowedSel := isAllowed(newEl, newPath, load, walked, info)
if !allowedSel {
info.illegals = append(info.illegals, &illegal{
T: "illegal-access",
Name: pck + "." + fun.name,
Pos: load[path].fset.Position(fun.pos).String(),
})
}
allowed = allowedSel && allowed
}
}
if !allowed {
info.illegals = append(info.illegals, &illegal{
T: "illegal-definition",
Name: fdef.Name,
Pos: load[path].fset.Position(funcNode.Pos()).String(),
})
}
return allowed
}
func removeRepetitions(slc []*illegal) []*illegal {
var result []*illegal
in := make(map[string]bool)
for _, v := range slc {
if in[v.Pos] {
continue
}
result = append(result, v)
in[v.Pos] = true
}
return result
}
type occurrence struct {
name string
pos string
}
type info struct {
arrays []*occurrence
lits []*occurrence
fors []*occurrence
callRep map[string]int
illegals []*illegal // functions, selections that are not allowed
}
func analyseProgram(functions []*fDefInfo, path string, load loadedSource) *info {
info := &info{
callRep: make(map[string]int),
}
walked := make(map[ast.Node]bool)
for _, v := range functions {
f := element{
name: v.obj.Name,
pos: token.Pos(0),
}
isAllowed(f, path, load, walked, info)
}
info.illegals = removeRepetitions(info.illegals)
return info
}
//reformat from the data base
func splitArgs(args string) []string {
result := strings.Split(args, " ")
return result
}
func rightFile(args string) string {
expectedFiles := splitArgs(args)
for _, s := range expectedFiles {
if strings.Contains(s, ".go") {
return s
}
}
return ""
}
type flags struct {
l struct { // flag for char or string literal
noLit bool // true -> unallows
pattern string // this pattern
}
}
// TODO: treat all the flags in this function
// For now, only --no-lit="{PATTERN}"
func parseFlags(args []string) *flags {
f := &flags{}
for _, v := range args {
var flag []string
if strings.Contains(v, "=") {
flag = strings.Split(v, "=")
}
if flag == nil {
continue
}
if flag[0] == "--no-lit" {
f.l.noLit = true
f.l.pattern = flag[1]
}
}
return f
}
func removeAmount(s string) string {
strRm := strings.TrimFunc(s, func(c rune) bool {
return c >= '0' && c <= '9' || c == '#'
})
return strRm
}
func init() {
flag.Var(&noTheseArrays, "no-these-arrays", "unallowes the array types passed in the flag")
flag.Var(&noLit, "no-lit",
`The use of string literals matching the pattern --no-lit="{PATTERN}"`+
`passed to the program would not be allowed`,
)
flag.BoolVar(&noRelativeImports, "no-relative-imports", false, `No disallowes the use of relative imports`)
flag.BoolVar(&noFor, "no-for", false, `The "for" instruction is not allowed`)
flag.BoolVar(&casting, "cast", false, "allowes casting")
flag.BoolVar(&noArrays, "no-arrays", false, "unallowes the array types passed in the flag")
flag.BoolVar(&allowBuiltin, "allow-builtin", false, "Allowes all builtin functions and casting")
}
func parseArgs(toAllow []string, builtins bool, casting bool) error {
allowedFun["builtin"] = make(map[string]bool)
predeclaredTypes := []string{"bool", "byte", "complex64", "complex128",
"error", "float32", "float64", "int", "int8",
"int16", "int32", "int64", "rune", "string",
"uint", "uint8", "uint16", "uint32", "uint64",
"uintptr",
}
if builtins {
allowedFun["builtin"]["*"] = true
}
if casting {
for _, v := range predeclaredTypes {
allowedFun["builtin"][v] = true
}
}
for _, v := range toAllow {
var path, funcName string
if strings.ContainsRune(v, '/') {
path = filepath.Dir(v)
funcName = filepath.Base(v)
spl := strings.Split(funcName, ".")
path = path + "/" + spl[0]
funcName = spl[1]
} else if strings.ContainsRune(v, '.') {
spl := strings.Split(v, ".")
path = spl[0]
funcName = spl[1]
} else {
path = "builtin"
funcName = v
}
if strings.ContainsRune(funcName, '#') {
spl := strings.Split(funcName, "#")
funcName = spl[0]
n, err := strconv.Atoi(spl[1])
if err != nil {
return fmt.Errorf("After the '#' there should be a integer" +
" representing the maximum number of allowed occurrences")
}
var prefix string
if path != "" {
prefix = filepath.Base(path)
}
allowedRep[prefix+"."+funcName] = n
}
if allowedFun[path] == nil {
allowedFun[path] = make(map[string]bool)
}
allowedFun[path][funcName] = true
}
return nil
}
func main() {
flag.Parse()
if flag.NArg() < 1 {
fmt.Println("Not enough arguments: missing file")
os.Exit(1)
}
fmt.Println("Parsing:")
err := parseArgs(flag.Args()[1:], allowBuiltin, casting)
if err != nil {
panic(err)
}
FileSet := token.NewFileSet()
file, err := parser.ParseFile(FileSet, flag.Arg(0), nil, parser.AllErrors)
if err != nil {
panic(err)
}
load := make(loadedSource)
currentPath := filepath.Dir(flag.Arg(0))
err = loadProgram(currentPath, load)
if err != nil {
panic(err)
}
fmt.Println("\tOk")
fmt.Println("Cheating:")
// Functions defined in the file
fileFunc := defs(file)
info := analyseProgram(fileFunc, currentPath, load)
info.illegals = append(analyseImports(file, FileSet, noRelativeImports), info.illegals...)
if noFor {
for _, v := range info.fors {
il := &illegal{
T: "illegal-loop",
Name: v.name,
Pos: v.pos,
}
info.illegals = append(info.illegals, il)
}
}
for _, v := range info.arrays {
if noArrays || noTheseArrays[v.name] {
il := &illegal{
T: "illegal-array",
Name: v.name,
Pos: v.pos,
}
info.illegals = append(info.illegals, il)
}
}
if noLit.active {
for _, v := range info.lits {
if noLit.reg.Match([]byte(v.name)) {
il := &illegal{
T: "illegal-lit",
Name: v.name,
Pos: v.pos,
}
info.illegals = append(info.illegals, il)
}
}
}
for name, rep := range allowedRep {
if info.callRep[name] > rep {
diff := info.callRep[name] - rep
il := &illegal{
T: "illegal-amount",
Name: name + " exeding max repetitions by " + strconv.Itoa(diff),
Pos: "all the project",
}
info.illegals = append(info.illegals, il)
}
}
info.illegals = removeRepetitions(info.illegals)
if info.illegals != nil {
tbl, err := table.NewTable([]table.Column{
{Header: "\tTYPE:"},
{Header: "NAME:", MinWidth: 7},
{Header: "LOCATION:"},
}...)
if err != nil {
panic(err)
}
tbl.Separator = "\t"
for _, v := range info.illegals {
tbl.AddRow("\t"+v.T, v.Name, v.Pos)
}
tbl.Print()
os.Exit(1)
}
fmt.Println("\tOk")
}
type importVisitor struct {
imports map[string]*element
}
func (i *importVisitor) Visit(n ast.Node) ast.Visitor {
if imp, ok := n.(*ast.ImportSpec); ok {
path, _ := strconv.Unquote(imp.Path.Value)
var name string
if imp.Name != nil {
name = imp.Name.Name
} else {
name = filepath.Base(path)
}
el := &element{
name: path,
pos: n.Pos(),
}
i.imports[name] = el
}
return i
}
func analyseImports(n ast.Node, fset *token.FileSet, noRelImp bool) []*illegal {
var il []*illegal
i := &importVisitor{
imports: make(map[string]*element),
}
ast.Walk(i, n)
for _, path := range i.imports {
isRelativeImport := isRelativeImport(path.name)
if (noRelativeImports && isRelativeImport) || (allowedFun[path.name] == nil && !isRelativeImport) {
il = append(il, &illegal{
T: "illegal-import",
Name: path.name,
Pos: fset.Position(path.pos).String(),
})
}
}
return il
}
type element struct {
name string
pos token.Pos
}
type loadVisitor struct {
relImports map[string]*element
absImports map[string]*element
functions map[string]ast.Node
fset *token.FileSet
objFunc map[*ast.Object]ast.Node
blocks []*ast.BlockStmt
scopes map[*ast.BlockStmt]*ast.Scope // nil after the visit
// used to keep the result of the createScope function
pkgScope *ast.Scope
}
// Returns all the parameter of a function that identify a function
func listParamFunc(params *ast.FieldList) []string {
var funcs []string
for _, param := range params.List {
if _, ok := param.Type.(*ast.FuncType); ok {
for _, name := range param.Names {
funcs = append(funcs, name.Name)
}
}
}
return funcs
}
type fDefInfo struct {
obj *ast.Object // the object that represents a function
paramsFunc []string // the name of the parameter that represent
// functions
body *ast.BlockStmt
}
// Returns information about a node representing a function declaration
func funcInfo(n ast.Node) *fDefInfo {
fdef := &fDefInfo{}
switch t := n.(type) {
case *ast.FuncDecl:
fdef.obj = t.Name.Obj
fdef.paramsFunc = listParamFunc(t.Type.Params)
fdef.body = t.Body
return fdef
case *ast.GenDecl:
for _, v := range t.Specs {
if val, ok := v.(*ast.ValueSpec); ok {
for i, value := range val.Values {
if funcLit, ok := value.(*ast.FuncLit); ok {
fdef.obj = val.Names[i].Obj
fdef.paramsFunc = listParamFunc(funcLit.Type.Params)
fdef.body = funcLit.Body
}
}
}
}
return fdef
case *ast.AssignStmt:
for i, right := range t.Rhs {
if funcLit, ok := right.(*ast.FuncLit); ok {
if ident, ok := t.Lhs[i].(*ast.Ident); ok {
fdef.obj = ident.Obj
fdef.paramsFunc = listParamFunc(funcLit.Type.Params)
}
}
return fdef
}
default:
return fdef
}
return fdef
}
func (l *loadVisitor) Visit(n ast.Node) ast.Visitor {
switch t := n.(type) {
case *ast.ImportSpec:
path, _ := strconv.Unquote(t.Path.Value)
var name string
if t.Name != nil {
name = t.Name.Name
} else {
name = filepath.Base(path)
}
el := &element{
name: path,
pos: n.Pos(),
}
if isRelativeImport(path) {
l.relImports[name] = el
break
}
l.absImports[name] = el
case *ast.FuncDecl, *ast.GenDecl, *ast.AssignStmt:
fdef := funcInfo(t)
if fdef == nil || fdef.obj == nil {
return l
}
l.objFunc[fdef.obj] = n
case *ast.BlockStmt:
l.blocks = append(l.blocks, t)
}
return l
}
func (f flags) isLitAllowed(s string) bool {
matched, err := regexp.Match(f.l.pattern, []byte(s))
if err != nil {
return true
}
return !matched
}
// Returns true if the string matches the format of a relative import
func isRelativeImport(s string) bool {
reg := regexp.MustCompile(`^\.`)
return reg.Match([]byte(s))
}