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plugeth/vendor/github.com/robertkrimen/otto/cmpl_evaluate_expression.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

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package otto
import (
"fmt"
"math"
"runtime"
"github.com/robertkrimen/otto/token"
)
func (self *_runtime) cmpl_evaluate_nodeExpression(node _nodeExpression) Value {
// Allow interpreter interruption
// If the Interrupt channel is nil, then
// we avoid runtime.Gosched() overhead (if any)
// FIXME: Test this
if self.otto.Interrupt != nil {
runtime.Gosched()
select {
case value := <-self.otto.Interrupt:
value()
default:
}
}
switch node := node.(type) {
case *_nodeArrayLiteral:
return self.cmpl_evaluate_nodeArrayLiteral(node)
case *_nodeAssignExpression:
return self.cmpl_evaluate_nodeAssignExpression(node)
case *_nodeBinaryExpression:
if node.comparison {
return self.cmpl_evaluate_nodeBinaryExpression_comparison(node)
} else {
return self.cmpl_evaluate_nodeBinaryExpression(node)
}
case *_nodeBracketExpression:
return self.cmpl_evaluate_nodeBracketExpression(node)
case *_nodeCallExpression:
return self.cmpl_evaluate_nodeCallExpression(node, nil)
case *_nodeConditionalExpression:
return self.cmpl_evaluate_nodeConditionalExpression(node)
case *_nodeDotExpression:
return self.cmpl_evaluate_nodeDotExpression(node)
case *_nodeFunctionLiteral:
var local = self.scope.lexical
if node.name != "" {
local = self.newDeclarationStash(local)
}
value := toValue_object(self.newNodeFunction(node, local))
if node.name != "" {
local.createBinding(node.name, false, value)
}
return value
case *_nodeIdentifier:
name := node.name
// TODO Should be true or false (strictness) depending on context
// getIdentifierReference should not return nil, but we check anyway and panic
// so as not to propagate the nil into something else
reference := getIdentifierReference(self, self.scope.lexical, name, false, _at(node.idx))
if reference == nil {
// Should never get here!
panic(hereBeDragons("referenceError == nil: " + name))
}
return toValue(reference)
case *_nodeLiteral:
return node.value
case *_nodeNewExpression:
return self.cmpl_evaluate_nodeNewExpression(node)
case *_nodeObjectLiteral:
return self.cmpl_evaluate_nodeObjectLiteral(node)
case *_nodeRegExpLiteral:
return toValue_object(self._newRegExp(node.pattern, node.flags))
case *_nodeSequenceExpression:
return self.cmpl_evaluate_nodeSequenceExpression(node)
case *_nodeThisExpression:
return toValue_object(self.scope.this)
case *_nodeUnaryExpression:
return self.cmpl_evaluate_nodeUnaryExpression(node)
case *_nodeVariableExpression:
return self.cmpl_evaluate_nodeVariableExpression(node)
}
panic(fmt.Errorf("Here be dragons: evaluate_nodeExpression(%T)", node))
}
func (self *_runtime) cmpl_evaluate_nodeArrayLiteral(node *_nodeArrayLiteral) Value {
valueArray := []Value{}
for _, node := range node.value {
if node == nil {
valueArray = append(valueArray, emptyValue)
} else {
valueArray = append(valueArray, self.cmpl_evaluate_nodeExpression(node).resolve())
}
}
result := self.newArrayOf(valueArray)
return toValue_object(result)
}
func (self *_runtime) cmpl_evaluate_nodeAssignExpression(node *_nodeAssignExpression) Value {
left := self.cmpl_evaluate_nodeExpression(node.left)
right := self.cmpl_evaluate_nodeExpression(node.right)
rightValue := right.resolve()
result := rightValue
if node.operator != token.ASSIGN {
result = self.calculateBinaryExpression(node.operator, left, rightValue)
}
self.putValue(left.reference(), result)
return result
}
func (self *_runtime) cmpl_evaluate_nodeBinaryExpression(node *_nodeBinaryExpression) Value {
left := self.cmpl_evaluate_nodeExpression(node.left)
leftValue := left.resolve()
switch node.operator {
// Logical
case token.LOGICAL_AND:
if !leftValue.bool() {
return leftValue
}
right := self.cmpl_evaluate_nodeExpression(node.right)
return right.resolve()
case token.LOGICAL_OR:
if leftValue.bool() {
return leftValue
}
right := self.cmpl_evaluate_nodeExpression(node.right)
return right.resolve()
}
return self.calculateBinaryExpression(node.operator, leftValue, self.cmpl_evaluate_nodeExpression(node.right))
}
func (self *_runtime) cmpl_evaluate_nodeBinaryExpression_comparison(node *_nodeBinaryExpression) Value {
left := self.cmpl_evaluate_nodeExpression(node.left).resolve()
right := self.cmpl_evaluate_nodeExpression(node.right).resolve()
return toValue_bool(self.calculateComparison(node.operator, left, right))
}
func (self *_runtime) cmpl_evaluate_nodeBracketExpression(node *_nodeBracketExpression) Value {
target := self.cmpl_evaluate_nodeExpression(node.left)
targetValue := target.resolve()
member := self.cmpl_evaluate_nodeExpression(node.member)
memberValue := member.resolve()
// TODO Pass in base value as-is, and defer toObject till later?
object, err := self.objectCoerce(targetValue)
if err != nil {
panic(self.panicTypeError("Cannot access member '%s' of %s", memberValue.string(), err.Error(), _at(node.idx)))
}
return toValue(newPropertyReference(self, object, memberValue.string(), false, _at(node.idx)))
}
func (self *_runtime) cmpl_evaluate_nodeCallExpression(node *_nodeCallExpression, withArgumentList []interface{}) Value {
rt := self
this := Value{}
callee := self.cmpl_evaluate_nodeExpression(node.callee)
argumentList := []Value{}
if withArgumentList != nil {
argumentList = self.toValueArray(withArgumentList...)
} else {
for _, argumentNode := range node.argumentList {
argumentList = append(argumentList, self.cmpl_evaluate_nodeExpression(argumentNode).resolve())
}
}
rf := callee.reference()
vl := callee.resolve()
eval := false // Whether this call is a (candidate for) direct call to eval
name := ""
if rf != nil {
switch rf := rf.(type) {
case *_propertyReference:
name = rf.name
object := rf.base
this = toValue_object(object)
eval = rf.name == "eval" // Possible direct eval
case *_stashReference:
// TODO ImplicitThisValue
name = rf.name
eval = rf.name == "eval" // Possible direct eval
default:
// FIXME?
panic(rt.panicTypeError("Here be dragons"))
}
}
at := _at(-1)
switch callee := node.callee.(type) {
case *_nodeIdentifier:
at = _at(callee.idx)
case *_nodeDotExpression:
at = _at(callee.idx)
case *_nodeBracketExpression:
at = _at(callee.idx)
}
frame := _frame{
callee: name,
file: self.scope.frame.file,
}
if !vl.IsFunction() {
if name == "" {
// FIXME Maybe typeof?
panic(rt.panicTypeError("%v is not a function", vl, at))
}
panic(rt.panicTypeError("'%s' is not a function", name, at))
}
self.scope.frame.offset = int(at)
return vl._object().call(this, argumentList, eval, frame)
}
func (self *_runtime) cmpl_evaluate_nodeConditionalExpression(node *_nodeConditionalExpression) Value {
test := self.cmpl_evaluate_nodeExpression(node.test)
testValue := test.resolve()
if testValue.bool() {
return self.cmpl_evaluate_nodeExpression(node.consequent)
}
return self.cmpl_evaluate_nodeExpression(node.alternate)
}
func (self *_runtime) cmpl_evaluate_nodeDotExpression(node *_nodeDotExpression) Value {
target := self.cmpl_evaluate_nodeExpression(node.left)
targetValue := target.resolve()
// TODO Pass in base value as-is, and defer toObject till later?
object, err := self.objectCoerce(targetValue)
if err != nil {
panic(self.panicTypeError("Cannot access member '%s' of %s", node.identifier, err.Error(), _at(node.idx)))
}
return toValue(newPropertyReference(self, object, node.identifier, false, _at(node.idx)))
}
func (self *_runtime) cmpl_evaluate_nodeNewExpression(node *_nodeNewExpression) Value {
rt := self
callee := self.cmpl_evaluate_nodeExpression(node.callee)
argumentList := []Value{}
for _, argumentNode := range node.argumentList {
argumentList = append(argumentList, self.cmpl_evaluate_nodeExpression(argumentNode).resolve())
}
rf := callee.reference()
vl := callee.resolve()
name := ""
if rf != nil {
switch rf := rf.(type) {
case *_propertyReference:
name = rf.name
case *_stashReference:
name = rf.name
default:
panic(rt.panicTypeError("Here be dragons"))
}
}
at := _at(-1)
switch callee := node.callee.(type) {
case *_nodeIdentifier:
at = _at(callee.idx)
case *_nodeDotExpression:
at = _at(callee.idx)
case *_nodeBracketExpression:
at = _at(callee.idx)
}
if !vl.IsFunction() {
if name == "" {
// FIXME Maybe typeof?
panic(rt.panicTypeError("%v is not a function", vl, at))
}
panic(rt.panicTypeError("'%s' is not a function", name, at))
}
self.scope.frame.offset = int(at)
return vl._object().construct(argumentList)
}
func (self *_runtime) cmpl_evaluate_nodeObjectLiteral(node *_nodeObjectLiteral) Value {
result := self.newObject()
for _, property := range node.value {
switch property.kind {
case "value":
result.defineProperty(property.key, self.cmpl_evaluate_nodeExpression(property.value).resolve(), 0111, false)
case "get":
getter := self.newNodeFunction(property.value.(*_nodeFunctionLiteral), self.scope.lexical)
descriptor := _property{}
descriptor.mode = 0211
descriptor.value = _propertyGetSet{getter, nil}
result.defineOwnProperty(property.key, descriptor, false)
case "set":
setter := self.newNodeFunction(property.value.(*_nodeFunctionLiteral), self.scope.lexical)
descriptor := _property{}
descriptor.mode = 0211
descriptor.value = _propertyGetSet{nil, setter}
result.defineOwnProperty(property.key, descriptor, false)
default:
panic(fmt.Errorf("Here be dragons: evaluate_nodeObjectLiteral: invalid property.Kind: %v", property.kind))
}
}
return toValue_object(result)
}
func (self *_runtime) cmpl_evaluate_nodeSequenceExpression(node *_nodeSequenceExpression) Value {
var result Value
for _, node := range node.sequence {
result = self.cmpl_evaluate_nodeExpression(node)
result = result.resolve()
}
return result
}
func (self *_runtime) cmpl_evaluate_nodeUnaryExpression(node *_nodeUnaryExpression) Value {
target := self.cmpl_evaluate_nodeExpression(node.operand)
switch node.operator {
case token.TYPEOF, token.DELETE:
if target.kind == valueReference && target.reference().invalid() {
if node.operator == token.TYPEOF {
return toValue_string("undefined")
}
return trueValue
}
}
switch node.operator {
case token.NOT:
targetValue := target.resolve()
if targetValue.bool() {
return falseValue
}
return trueValue
case token.BITWISE_NOT:
targetValue := target.resolve()
integerValue := toInt32(targetValue)
return toValue_int32(^integerValue)
case token.PLUS:
targetValue := target.resolve()
return toValue_float64(targetValue.float64())
case token.MINUS:
targetValue := target.resolve()
value := targetValue.float64()
// TODO Test this
sign := float64(-1)
if math.Signbit(value) {
sign = 1
}
return toValue_float64(math.Copysign(value, sign))
case token.INCREMENT:
targetValue := target.resolve()
if node.postfix {
// Postfix++
oldValue := targetValue.float64()
newValue := toValue_float64(+1 + oldValue)
self.putValue(target.reference(), newValue)
return toValue_float64(oldValue)
} else {
// ++Prefix
newValue := toValue_float64(+1 + targetValue.float64())
self.putValue(target.reference(), newValue)
return newValue
}
case token.DECREMENT:
targetValue := target.resolve()
if node.postfix {
// Postfix--
oldValue := targetValue.float64()
newValue := toValue_float64(-1 + oldValue)
self.putValue(target.reference(), newValue)
return toValue_float64(oldValue)
} else {
// --Prefix
newValue := toValue_float64(-1 + targetValue.float64())
self.putValue(target.reference(), newValue)
return newValue
}
case token.VOID:
target.resolve() // FIXME Side effect?
return Value{}
case token.DELETE:
reference := target.reference()
if reference == nil {
return trueValue
}
return toValue_bool(target.reference().delete())
case token.TYPEOF:
targetValue := target.resolve()
switch targetValue.kind {
case valueUndefined:
return toValue_string("undefined")
case valueNull:
return toValue_string("object")
case valueBoolean:
return toValue_string("boolean")
case valueNumber:
return toValue_string("number")
case valueString:
return toValue_string("string")
case valueObject:
if targetValue._object().isCall() {
return toValue_string("function")
}
return toValue_string("object")
default:
// FIXME ?
}
}
panic(hereBeDragons())
}
func (self *_runtime) cmpl_evaluate_nodeVariableExpression(node *_nodeVariableExpression) Value {
if node.initializer != nil {
// FIXME If reference is nil
left := getIdentifierReference(self, self.scope.lexical, node.name, false, _at(node.idx))
right := self.cmpl_evaluate_nodeExpression(node.initializer)
rightValue := right.resolve()
self.putValue(left, rightValue)
}
return toValue_string(node.name)
}
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