bsc/vendor/github.com/robertkrimen/otto/cmpl_parse.go
Péter Szilágyi 289b30715d Godeps, vendor: convert dependency management to trash (#3198)
This commit converts the dependency management from Godeps to the vendor
folder, also switching the tool from godep to trash. Since the upstream tool
lacks a few features proposed via a few PRs, until those PRs are merged in
(if), use github.com/karalabe/trash.

You can update dependencies via trash --update.

All dependencies have been updated to their latest version.

Parts of the build system are reworked to drop old notions of Godeps and
invocation of the go vet command so that it doesn't run against the vendor
folder, as that will just blow up during vetting.

The conversion drops OpenCL (and hence GPU mining support) from ethash and our
codebase. The short reasoning is that there's noone to maintain and having
opencl libs in our deps messes up builds as go install ./... tries to build
them, failing with unsatisfied link errors for the C OpenCL deps.

golang.org/x/net/context is not vendored in. We expect it to be fetched by the
user (i.e. using go get). To keep ci.go builds reproducible the package is
"vendored" in build/_vendor.
2016-10-28 19:05:01 +02:00

657 lines
15 KiB
Go

package otto
import (
"fmt"
"regexp"
"github.com/robertkrimen/otto/ast"
"github.com/robertkrimen/otto/file"
"github.com/robertkrimen/otto/token"
)
var trueLiteral = &_nodeLiteral{value: toValue_bool(true)}
var falseLiteral = &_nodeLiteral{value: toValue_bool(false)}
var nullLiteral = &_nodeLiteral{value: nullValue}
var emptyStatement = &_nodeEmptyStatement{}
func (cmpl *_compiler) parseExpression(in ast.Expression) _nodeExpression {
if in == nil {
return nil
}
switch in := in.(type) {
case *ast.ArrayLiteral:
out := &_nodeArrayLiteral{
value: make([]_nodeExpression, len(in.Value)),
}
for i, value := range in.Value {
out.value[i] = cmpl.parseExpression(value)
}
return out
case *ast.AssignExpression:
return &_nodeAssignExpression{
operator: in.Operator,
left: cmpl.parseExpression(in.Left),
right: cmpl.parseExpression(in.Right),
}
case *ast.BinaryExpression:
return &_nodeBinaryExpression{
operator: in.Operator,
left: cmpl.parseExpression(in.Left),
right: cmpl.parseExpression(in.Right),
comparison: in.Comparison,
}
case *ast.BooleanLiteral:
if in.Value {
return trueLiteral
}
return falseLiteral
case *ast.BracketExpression:
return &_nodeBracketExpression{
idx: in.Left.Idx0(),
left: cmpl.parseExpression(in.Left),
member: cmpl.parseExpression(in.Member),
}
case *ast.CallExpression:
out := &_nodeCallExpression{
callee: cmpl.parseExpression(in.Callee),
argumentList: make([]_nodeExpression, len(in.ArgumentList)),
}
for i, value := range in.ArgumentList {
out.argumentList[i] = cmpl.parseExpression(value)
}
return out
case *ast.ConditionalExpression:
return &_nodeConditionalExpression{
test: cmpl.parseExpression(in.Test),
consequent: cmpl.parseExpression(in.Consequent),
alternate: cmpl.parseExpression(in.Alternate),
}
case *ast.DotExpression:
return &_nodeDotExpression{
idx: in.Left.Idx0(),
left: cmpl.parseExpression(in.Left),
identifier: in.Identifier.Name,
}
case *ast.EmptyExpression:
return nil
case *ast.FunctionLiteral:
name := ""
if in.Name != nil {
name = in.Name.Name
}
out := &_nodeFunctionLiteral{
name: name,
body: cmpl.parseStatement(in.Body),
source: in.Source,
file: cmpl.file,
}
if in.ParameterList != nil {
list := in.ParameterList.List
out.parameterList = make([]string, len(list))
for i, value := range list {
out.parameterList[i] = value.Name
}
}
for _, value := range in.DeclarationList {
switch value := value.(type) {
case *ast.FunctionDeclaration:
out.functionList = append(out.functionList, cmpl.parseExpression(value.Function).(*_nodeFunctionLiteral))
case *ast.VariableDeclaration:
for _, value := range value.List {
out.varList = append(out.varList, value.Name)
}
default:
panic(fmt.Errorf("Here be dragons: parseProgram.declaration(%T)", value))
}
}
return out
case *ast.Identifier:
return &_nodeIdentifier{
idx: in.Idx,
name: in.Name,
}
case *ast.NewExpression:
out := &_nodeNewExpression{
callee: cmpl.parseExpression(in.Callee),
argumentList: make([]_nodeExpression, len(in.ArgumentList)),
}
for i, value := range in.ArgumentList {
out.argumentList[i] = cmpl.parseExpression(value)
}
return out
case *ast.NullLiteral:
return nullLiteral
case *ast.NumberLiteral:
return &_nodeLiteral{
value: toValue(in.Value),
}
case *ast.ObjectLiteral:
out := &_nodeObjectLiteral{
value: make([]_nodeProperty, len(in.Value)),
}
for i, value := range in.Value {
out.value[i] = _nodeProperty{
key: value.Key,
kind: value.Kind,
value: cmpl.parseExpression(value.Value),
}
}
return out
case *ast.RegExpLiteral:
return &_nodeRegExpLiteral{
flags: in.Flags,
pattern: in.Pattern,
}
case *ast.SequenceExpression:
out := &_nodeSequenceExpression{
sequence: make([]_nodeExpression, len(in.Sequence)),
}
for i, value := range in.Sequence {
out.sequence[i] = cmpl.parseExpression(value)
}
return out
case *ast.StringLiteral:
return &_nodeLiteral{
value: toValue_string(in.Value),
}
case *ast.ThisExpression:
return &_nodeThisExpression{}
case *ast.UnaryExpression:
return &_nodeUnaryExpression{
operator: in.Operator,
operand: cmpl.parseExpression(in.Operand),
postfix: in.Postfix,
}
case *ast.VariableExpression:
return &_nodeVariableExpression{
idx: in.Idx0(),
name: in.Name,
initializer: cmpl.parseExpression(in.Initializer),
}
}
panic(fmt.Errorf("Here be dragons: cmpl.parseExpression(%T)", in))
}
func (cmpl *_compiler) parseStatement(in ast.Statement) _nodeStatement {
if in == nil {
return nil
}
switch in := in.(type) {
case *ast.BlockStatement:
out := &_nodeBlockStatement{
list: make([]_nodeStatement, len(in.List)),
}
for i, value := range in.List {
out.list[i] = cmpl.parseStatement(value)
}
return out
case *ast.BranchStatement:
out := &_nodeBranchStatement{
branch: in.Token,
}
if in.Label != nil {
out.label = in.Label.Name
}
return out
case *ast.DebuggerStatement:
return &_nodeDebuggerStatement{}
case *ast.DoWhileStatement:
out := &_nodeDoWhileStatement{
test: cmpl.parseExpression(in.Test),
}
body := cmpl.parseStatement(in.Body)
if block, ok := body.(*_nodeBlockStatement); ok {
out.body = block.list
} else {
out.body = append(out.body, body)
}
return out
case *ast.EmptyStatement:
return emptyStatement
case *ast.ExpressionStatement:
return &_nodeExpressionStatement{
expression: cmpl.parseExpression(in.Expression),
}
case *ast.ForInStatement:
out := &_nodeForInStatement{
into: cmpl.parseExpression(in.Into),
source: cmpl.parseExpression(in.Source),
}
body := cmpl.parseStatement(in.Body)
if block, ok := body.(*_nodeBlockStatement); ok {
out.body = block.list
} else {
out.body = append(out.body, body)
}
return out
case *ast.ForStatement:
out := &_nodeForStatement{
initializer: cmpl.parseExpression(in.Initializer),
update: cmpl.parseExpression(in.Update),
test: cmpl.parseExpression(in.Test),
}
body := cmpl.parseStatement(in.Body)
if block, ok := body.(*_nodeBlockStatement); ok {
out.body = block.list
} else {
out.body = append(out.body, body)
}
return out
case *ast.FunctionStatement:
return emptyStatement
case *ast.IfStatement:
return &_nodeIfStatement{
test: cmpl.parseExpression(in.Test),
consequent: cmpl.parseStatement(in.Consequent),
alternate: cmpl.parseStatement(in.Alternate),
}
case *ast.LabelledStatement:
return &_nodeLabelledStatement{
label: in.Label.Name,
statement: cmpl.parseStatement(in.Statement),
}
case *ast.ReturnStatement:
return &_nodeReturnStatement{
argument: cmpl.parseExpression(in.Argument),
}
case *ast.SwitchStatement:
out := &_nodeSwitchStatement{
discriminant: cmpl.parseExpression(in.Discriminant),
default_: in.Default,
body: make([]*_nodeCaseStatement, len(in.Body)),
}
for i, clause := range in.Body {
out.body[i] = &_nodeCaseStatement{
test: cmpl.parseExpression(clause.Test),
consequent: make([]_nodeStatement, len(clause.Consequent)),
}
for j, value := range clause.Consequent {
out.body[i].consequent[j] = cmpl.parseStatement(value)
}
}
return out
case *ast.ThrowStatement:
return &_nodeThrowStatement{
argument: cmpl.parseExpression(in.Argument),
}
case *ast.TryStatement:
out := &_nodeTryStatement{
body: cmpl.parseStatement(in.Body),
finally: cmpl.parseStatement(in.Finally),
}
if in.Catch != nil {
out.catch = &_nodeCatchStatement{
parameter: in.Catch.Parameter.Name,
body: cmpl.parseStatement(in.Catch.Body),
}
}
return out
case *ast.VariableStatement:
out := &_nodeVariableStatement{
list: make([]_nodeExpression, len(in.List)),
}
for i, value := range in.List {
out.list[i] = cmpl.parseExpression(value)
}
return out
case *ast.WhileStatement:
out := &_nodeWhileStatement{
test: cmpl.parseExpression(in.Test),
}
body := cmpl.parseStatement(in.Body)
if block, ok := body.(*_nodeBlockStatement); ok {
out.body = block.list
} else {
out.body = append(out.body, body)
}
return out
case *ast.WithStatement:
return &_nodeWithStatement{
object: cmpl.parseExpression(in.Object),
body: cmpl.parseStatement(in.Body),
}
}
panic(fmt.Errorf("Here be dragons: cmpl.parseStatement(%T)", in))
}
func cmpl_parse(in *ast.Program) *_nodeProgram {
cmpl := _compiler{
program: in,
}
return cmpl.parse()
}
func (cmpl *_compiler) _parse(in *ast.Program) *_nodeProgram {
out := &_nodeProgram{
body: make([]_nodeStatement, len(in.Body)),
file: in.File,
}
for i, value := range in.Body {
out.body[i] = cmpl.parseStatement(value)
}
for _, value := range in.DeclarationList {
switch value := value.(type) {
case *ast.FunctionDeclaration:
out.functionList = append(out.functionList, cmpl.parseExpression(value.Function).(*_nodeFunctionLiteral))
case *ast.VariableDeclaration:
for _, value := range value.List {
out.varList = append(out.varList, value.Name)
}
default:
panic(fmt.Errorf("Here be dragons: cmpl.parseProgram.DeclarationList(%T)", value))
}
}
return out
}
type _nodeProgram struct {
body []_nodeStatement
varList []string
functionList []*_nodeFunctionLiteral
variableList []_nodeDeclaration
file *file.File
}
type _nodeDeclaration struct {
name string
definition _node
}
type _node interface {
}
type (
_nodeExpression interface {
_node
_expressionNode()
}
_nodeArrayLiteral struct {
value []_nodeExpression
}
_nodeAssignExpression struct {
operator token.Token
left _nodeExpression
right _nodeExpression
}
_nodeBinaryExpression struct {
operator token.Token
left _nodeExpression
right _nodeExpression
comparison bool
}
_nodeBracketExpression struct {
idx file.Idx
left _nodeExpression
member _nodeExpression
}
_nodeCallExpression struct {
callee _nodeExpression
argumentList []_nodeExpression
}
_nodeConditionalExpression struct {
test _nodeExpression
consequent _nodeExpression
alternate _nodeExpression
}
_nodeDotExpression struct {
idx file.Idx
left _nodeExpression
identifier string
}
_nodeFunctionLiteral struct {
name string
body _nodeStatement
source string
parameterList []string
varList []string
functionList []*_nodeFunctionLiteral
file *file.File
}
_nodeIdentifier struct {
idx file.Idx
name string
}
_nodeLiteral struct {
value Value
}
_nodeNewExpression struct {
callee _nodeExpression
argumentList []_nodeExpression
}
_nodeObjectLiteral struct {
value []_nodeProperty
}
_nodeProperty struct {
key string
kind string
value _nodeExpression
}
_nodeRegExpLiteral struct {
flags string
pattern string // Value?
regexp *regexp.Regexp
}
_nodeSequenceExpression struct {
sequence []_nodeExpression
}
_nodeThisExpression struct {
}
_nodeUnaryExpression struct {
operator token.Token
operand _nodeExpression
postfix bool
}
_nodeVariableExpression struct {
idx file.Idx
name string
initializer _nodeExpression
}
)
type (
_nodeStatement interface {
_node
_statementNode()
}
_nodeBlockStatement struct {
list []_nodeStatement
}
_nodeBranchStatement struct {
branch token.Token
label string
}
_nodeCaseStatement struct {
test _nodeExpression
consequent []_nodeStatement
}
_nodeCatchStatement struct {
parameter string
body _nodeStatement
}
_nodeDebuggerStatement struct {
}
_nodeDoWhileStatement struct {
test _nodeExpression
body []_nodeStatement
}
_nodeEmptyStatement struct {
}
_nodeExpressionStatement struct {
expression _nodeExpression
}
_nodeForInStatement struct {
into _nodeExpression
source _nodeExpression
body []_nodeStatement
}
_nodeForStatement struct {
initializer _nodeExpression
update _nodeExpression
test _nodeExpression
body []_nodeStatement
}
_nodeIfStatement struct {
test _nodeExpression
consequent _nodeStatement
alternate _nodeStatement
}
_nodeLabelledStatement struct {
label string
statement _nodeStatement
}
_nodeReturnStatement struct {
argument _nodeExpression
}
_nodeSwitchStatement struct {
discriminant _nodeExpression
default_ int
body []*_nodeCaseStatement
}
_nodeThrowStatement struct {
argument _nodeExpression
}
_nodeTryStatement struct {
body _nodeStatement
catch *_nodeCatchStatement
finally _nodeStatement
}
_nodeVariableStatement struct {
list []_nodeExpression
}
_nodeWhileStatement struct {
test _nodeExpression
body []_nodeStatement
}
_nodeWithStatement struct {
object _nodeExpression
body _nodeStatement
}
)
// _expressionNode
func (*_nodeArrayLiteral) _expressionNode() {}
func (*_nodeAssignExpression) _expressionNode() {}
func (*_nodeBinaryExpression) _expressionNode() {}
func (*_nodeBracketExpression) _expressionNode() {}
func (*_nodeCallExpression) _expressionNode() {}
func (*_nodeConditionalExpression) _expressionNode() {}
func (*_nodeDotExpression) _expressionNode() {}
func (*_nodeFunctionLiteral) _expressionNode() {}
func (*_nodeIdentifier) _expressionNode() {}
func (*_nodeLiteral) _expressionNode() {}
func (*_nodeNewExpression) _expressionNode() {}
func (*_nodeObjectLiteral) _expressionNode() {}
func (*_nodeRegExpLiteral) _expressionNode() {}
func (*_nodeSequenceExpression) _expressionNode() {}
func (*_nodeThisExpression) _expressionNode() {}
func (*_nodeUnaryExpression) _expressionNode() {}
func (*_nodeVariableExpression) _expressionNode() {}
// _statementNode
func (*_nodeBlockStatement) _statementNode() {}
func (*_nodeBranchStatement) _statementNode() {}
func (*_nodeCaseStatement) _statementNode() {}
func (*_nodeCatchStatement) _statementNode() {}
func (*_nodeDebuggerStatement) _statementNode() {}
func (*_nodeDoWhileStatement) _statementNode() {}
func (*_nodeEmptyStatement) _statementNode() {}
func (*_nodeExpressionStatement) _statementNode() {}
func (*_nodeForInStatement) _statementNode() {}
func (*_nodeForStatement) _statementNode() {}
func (*_nodeIfStatement) _statementNode() {}
func (*_nodeLabelledStatement) _statementNode() {}
func (*_nodeReturnStatement) _statementNode() {}
func (*_nodeSwitchStatement) _statementNode() {}
func (*_nodeThrowStatement) _statementNode() {}
func (*_nodeTryStatement) _statementNode() {}
func (*_nodeVariableStatement) _statementNode() {}
func (*_nodeWhileStatement) _statementNode() {}
func (*_nodeWithStatement) _statementNode() {}