ceph-csi/vendor/github.com/onsi/ginkgo/v2/internal/node.go

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package internal
import (
"fmt"
"reflect"
"sort"
"sync"
"github.com/onsi/ginkgo/v2/types"
)
var _global_node_id_counter = uint(0)
var _global_id_mutex = &sync.Mutex{}
func UniqueNodeID() uint {
//There's a reace in the internal integration tests if we don't make
//accessing _global_node_id_counter safe across goroutines.
_global_id_mutex.Lock()
defer _global_id_mutex.Unlock()
_global_node_id_counter += 1
return _global_node_id_counter
}
type Node struct {
ID uint
NodeType types.NodeType
Text string
Body func()
CodeLocation types.CodeLocation
NestingLevel int
SynchronizedBeforeSuiteProc1Body func() []byte
SynchronizedBeforeSuiteAllProcsBody func([]byte)
SynchronizedAfterSuiteAllProcsBody func()
SynchronizedAfterSuiteProc1Body func()
ReportEachBody func(types.SpecReport)
ReportAfterSuiteBody func(types.Report)
MarkedFocus bool
MarkedPending bool
MarkedSerial bool
MarkedOrdered bool
MarkedOncePerOrdered bool
FlakeAttempts int
Labels Labels
NodeIDWhereCleanupWasGenerated uint
}
// Decoration Types
type focusType bool
type pendingType bool
type serialType bool
type orderedType bool
type honorsOrderedType bool
const Focus = focusType(true)
const Pending = pendingType(true)
const Serial = serialType(true)
const Ordered = orderedType(true)
const OncePerOrdered = honorsOrderedType(true)
type FlakeAttempts uint
type Offset uint
type Done chan<- interface{} // Deprecated Done Channel for asynchronous testing
type Labels []string
func UnionOfLabels(labels ...Labels) Labels {
out := Labels{}
seen := map[string]bool{}
for _, labelSet := range labels {
for _, label := range labelSet {
if !seen[label] {
seen[label] = true
out = append(out, label)
}
}
}
return out
}
func PartitionDecorations(args ...interface{}) ([]interface{}, []interface{}) {
decorations := []interface{}{}
remainingArgs := []interface{}{}
for _, arg := range args {
if isDecoration(arg) {
decorations = append(decorations, arg)
} else {
remainingArgs = append(remainingArgs, arg)
}
}
return decorations, remainingArgs
}
func isDecoration(arg interface{}) bool {
switch t := reflect.TypeOf(arg); {
case t == nil:
return false
case t == reflect.TypeOf(Offset(0)):
return true
case t == reflect.TypeOf(types.CodeLocation{}):
return true
case t == reflect.TypeOf(Focus):
return true
case t == reflect.TypeOf(Pending):
return true
case t == reflect.TypeOf(Serial):
return true
case t == reflect.TypeOf(Ordered):
return true
case t == reflect.TypeOf(OncePerOrdered):
return true
case t == reflect.TypeOf(FlakeAttempts(0)):
return true
case t == reflect.TypeOf(Labels{}):
return true
case t.Kind() == reflect.Slice && isSliceOfDecorations(arg):
return true
default:
return false
}
}
func isSliceOfDecorations(slice interface{}) bool {
vSlice := reflect.ValueOf(slice)
if vSlice.Len() == 0 {
return false
}
for i := 0; i < vSlice.Len(); i++ {
if !isDecoration(vSlice.Index(i).Interface()) {
return false
}
}
return true
}
func NewNode(deprecationTracker *types.DeprecationTracker, nodeType types.NodeType, text string, args ...interface{}) (Node, []error) {
baseOffset := 2
node := Node{
ID: UniqueNodeID(),
NodeType: nodeType,
Text: text,
Labels: Labels{},
CodeLocation: types.NewCodeLocation(baseOffset),
NestingLevel: -1,
}
errors := []error{}
appendError := func(err error) {
if err != nil {
errors = append(errors, err)
}
}
args = unrollInterfaceSlice(args)
remainingArgs := []interface{}{}
//First get the CodeLocation up-to-date
for _, arg := range args {
switch v := arg.(type) {
case Offset:
node.CodeLocation = types.NewCodeLocation(baseOffset + int(v))
case types.CodeLocation:
node.CodeLocation = v
default:
remainingArgs = append(remainingArgs, arg)
}
}
labelsSeen := map[string]bool{}
trackedFunctionError := false
args = remainingArgs
remainingArgs = []interface{}{}
//now process the rest of the args
for _, arg := range args {
switch t := reflect.TypeOf(arg); {
case t == reflect.TypeOf(float64(0)):
break //ignore deprecated timeouts
case t == reflect.TypeOf(Focus):
node.MarkedFocus = bool(arg.(focusType))
if !nodeType.Is(types.NodeTypesForContainerAndIt) {
appendError(types.GinkgoErrors.InvalidDecoratorForNodeType(node.CodeLocation, nodeType, "Focus"))
}
case t == reflect.TypeOf(Pending):
node.MarkedPending = bool(arg.(pendingType))
if !nodeType.Is(types.NodeTypesForContainerAndIt) {
appendError(types.GinkgoErrors.InvalidDecoratorForNodeType(node.CodeLocation, nodeType, "Pending"))
}
case t == reflect.TypeOf(Serial):
node.MarkedSerial = bool(arg.(serialType))
if !nodeType.Is(types.NodeTypesForContainerAndIt) {
appendError(types.GinkgoErrors.InvalidDecoratorForNodeType(node.CodeLocation, nodeType, "Serial"))
}
case t == reflect.TypeOf(Ordered):
node.MarkedOrdered = bool(arg.(orderedType))
if !nodeType.Is(types.NodeTypeContainer) {
appendError(types.GinkgoErrors.InvalidDecoratorForNodeType(node.CodeLocation, nodeType, "Ordered"))
}
case t == reflect.TypeOf(OncePerOrdered):
node.MarkedOncePerOrdered = bool(arg.(honorsOrderedType))
if !nodeType.Is(types.NodeTypeBeforeEach | types.NodeTypeJustBeforeEach | types.NodeTypeAfterEach | types.NodeTypeJustAfterEach) {
appendError(types.GinkgoErrors.InvalidDecoratorForNodeType(node.CodeLocation, nodeType, "OncePerOrdered"))
}
case t == reflect.TypeOf(FlakeAttempts(0)):
node.FlakeAttempts = int(arg.(FlakeAttempts))
if !nodeType.Is(types.NodeTypesForContainerAndIt) {
appendError(types.GinkgoErrors.InvalidDecoratorForNodeType(node.CodeLocation, nodeType, "FlakeAttempts"))
}
case t == reflect.TypeOf(Labels{}):
if !nodeType.Is(types.NodeTypesForContainerAndIt) {
appendError(types.GinkgoErrors.InvalidDecoratorForNodeType(node.CodeLocation, nodeType, "Label"))
}
for _, label := range arg.(Labels) {
if !labelsSeen[label] {
labelsSeen[label] = true
label, err := types.ValidateAndCleanupLabel(label, node.CodeLocation)
node.Labels = append(node.Labels, label)
appendError(err)
}
}
case t.Kind() == reflect.Func:
if node.Body != nil {
appendError(types.GinkgoErrors.MultipleBodyFunctions(node.CodeLocation, nodeType))
trackedFunctionError = true
break
}
isValid := (t.NumOut() == 0) && (t.NumIn() <= 1) && (t.NumIn() == 0 || t.In(0) == reflect.TypeOf(make(Done)))
if !isValid {
appendError(types.GinkgoErrors.InvalidBodyType(t, node.CodeLocation, nodeType))
trackedFunctionError = true
break
}
if t.NumIn() == 0 {
node.Body = arg.(func())
} else {
deprecationTracker.TrackDeprecation(types.Deprecations.Async(), node.CodeLocation)
deprecatedAsyncBody := arg.(func(Done))
node.Body = func() { deprecatedAsyncBody(make(Done)) }
}
default:
remainingArgs = append(remainingArgs, arg)
}
}
//validations
if node.MarkedPending && node.MarkedFocus {
appendError(types.GinkgoErrors.InvalidDeclarationOfFocusedAndPending(node.CodeLocation, nodeType))
}
if node.Body == nil && !node.MarkedPending && !trackedFunctionError {
appendError(types.GinkgoErrors.MissingBodyFunction(node.CodeLocation, nodeType))
}
for _, arg := range remainingArgs {
appendError(types.GinkgoErrors.UnknownDecorator(node.CodeLocation, nodeType, arg))
}
if len(errors) > 0 {
return Node{}, errors
}
return node, errors
}
func NewSynchronizedBeforeSuiteNode(proc1Body func() []byte, allProcsBody func([]byte), codeLocation types.CodeLocation) (Node, []error) {
return Node{
ID: UniqueNodeID(),
NodeType: types.NodeTypeSynchronizedBeforeSuite,
SynchronizedBeforeSuiteProc1Body: proc1Body,
SynchronizedBeforeSuiteAllProcsBody: allProcsBody,
CodeLocation: codeLocation,
}, nil
}
func NewSynchronizedAfterSuiteNode(allProcsBody func(), proc1Body func(), codeLocation types.CodeLocation) (Node, []error) {
return Node{
ID: UniqueNodeID(),
NodeType: types.NodeTypeSynchronizedAfterSuite,
SynchronizedAfterSuiteAllProcsBody: allProcsBody,
SynchronizedAfterSuiteProc1Body: proc1Body,
CodeLocation: codeLocation,
}, nil
}
func NewReportBeforeEachNode(body func(types.SpecReport), codeLocation types.CodeLocation) (Node, []error) {
return Node{
ID: UniqueNodeID(),
NodeType: types.NodeTypeReportBeforeEach,
ReportEachBody: body,
CodeLocation: codeLocation,
NestingLevel: -1,
}, nil
}
func NewReportAfterEachNode(body func(types.SpecReport), codeLocation types.CodeLocation) (Node, []error) {
return Node{
ID: UniqueNodeID(),
NodeType: types.NodeTypeReportAfterEach,
ReportEachBody: body,
CodeLocation: codeLocation,
NestingLevel: -1,
}, nil
}
func NewReportAfterSuiteNode(text string, body func(types.Report), codeLocation types.CodeLocation) (Node, []error) {
return Node{
ID: UniqueNodeID(),
Text: text,
NodeType: types.NodeTypeReportAfterSuite,
ReportAfterSuiteBody: body,
CodeLocation: codeLocation,
}, nil
}
func NewCleanupNode(fail func(string, types.CodeLocation), args ...interface{}) (Node, []error) {
baseOffset := 2
node := Node{
ID: UniqueNodeID(),
NodeType: types.NodeTypeCleanupInvalid,
CodeLocation: types.NewCodeLocation(baseOffset),
NestingLevel: -1,
}
remainingArgs := []interface{}{}
for _, arg := range args {
switch t := reflect.TypeOf(arg); {
case t == reflect.TypeOf(Offset(0)):
node.CodeLocation = types.NewCodeLocation(baseOffset + int(arg.(Offset)))
case t == reflect.TypeOf(types.CodeLocation{}):
node.CodeLocation = arg.(types.CodeLocation)
default:
remainingArgs = append(remainingArgs, arg)
}
}
if len(remainingArgs) == 0 {
return Node{}, []error{types.GinkgoErrors.DeferCleanupInvalidFunction(node.CodeLocation)}
}
callback := reflect.ValueOf(remainingArgs[0])
if !(callback.Kind() == reflect.Func && callback.Type().NumOut() <= 1) {
return Node{}, []error{types.GinkgoErrors.DeferCleanupInvalidFunction(node.CodeLocation)}
}
callArgs := []reflect.Value{}
for _, arg := range remainingArgs[1:] {
callArgs = append(callArgs, reflect.ValueOf(arg))
}
cl := node.CodeLocation
node.Body = func() {
out := callback.Call(callArgs)
if len(out) == 1 && !out[0].IsNil() {
fail(fmt.Sprintf("DeferCleanup callback returned error: %v", out[0]), cl)
}
}
return node, nil
}
func (n Node) IsZero() bool {
return n.ID == 0
}
/* Nodes */
type Nodes []Node
func (n Nodes) CopyAppend(nodes ...Node) Nodes {
numN := len(n)
out := make(Nodes, numN+len(nodes))
for i, node := range n {
out[i] = node
}
for j, node := range nodes {
out[numN+j] = node
}
return out
}
func (n Nodes) SplitAround(pivot Node) (Nodes, Nodes) {
pivotIdx := len(n)
for i := range n {
if n[i].ID == pivot.ID {
pivotIdx = i
break
}
}
left := n[:pivotIdx]
right := Nodes{}
if pivotIdx+1 < len(n) {
right = n[pivotIdx+1:]
}
return left, right
}
func (n Nodes) FirstNodeWithType(nodeTypes types.NodeType) Node {
for i := range n {
if n[i].NodeType.Is(nodeTypes) {
return n[i]
}
}
return Node{}
}
func (n Nodes) WithType(nodeTypes types.NodeType) Nodes {
count := 0
for i := range n {
if n[i].NodeType.Is(nodeTypes) {
count++
}
}
out, j := make(Nodes, count), 0
for i := range n {
if n[i].NodeType.Is(nodeTypes) {
out[j] = n[i]
j++
}
}
return out
}
func (n Nodes) WithoutType(nodeTypes types.NodeType) Nodes {
count := 0
for i := range n {
if !n[i].NodeType.Is(nodeTypes) {
count++
}
}
out, j := make(Nodes, count), 0
for i := range n {
if !n[i].NodeType.Is(nodeTypes) {
out[j] = n[i]
j++
}
}
return out
}
func (n Nodes) WithoutNode(nodeToExclude Node) Nodes {
idxToExclude := len(n)
for i := range n {
if n[i].ID == nodeToExclude.ID {
idxToExclude = i
break
}
}
if idxToExclude == len(n) {
return n
}
out, j := make(Nodes, len(n)-1), 0
for i := range n {
if i == idxToExclude {
continue
}
out[j] = n[i]
j++
}
return out
}
func (n Nodes) Filter(filter func(Node) bool) Nodes {
trufa, count := make([]bool, len(n)), 0
for i := range n {
if filter(n[i]) {
trufa[i] = true
count += 1
}
}
out, j := make(Nodes, count), 0
for i := range n {
if trufa[i] {
out[j] = n[i]
j++
}
}
return out
}
func (n Nodes) FirstSatisfying(filter func(Node) bool) Node {
for i := range n {
if filter(n[i]) {
return n[i]
}
}
return Node{}
}
func (n Nodes) WithinNestingLevel(deepestNestingLevel int) Nodes {
count := 0
for i := range n {
if n[i].NestingLevel <= deepestNestingLevel {
count++
}
}
out, j := make(Nodes, count), 0
for i := range n {
if n[i].NestingLevel <= deepestNestingLevel {
out[j] = n[i]
j++
}
}
return out
}
func (n Nodes) SortedByDescendingNestingLevel() Nodes {
out := make(Nodes, len(n))
copy(out, n)
sort.SliceStable(out, func(i int, j int) bool {
return out[i].NestingLevel > out[j].NestingLevel
})
return out
}
func (n Nodes) SortedByAscendingNestingLevel() Nodes {
out := make(Nodes, len(n))
copy(out, n)
sort.SliceStable(out, func(i int, j int) bool {
return out[i].NestingLevel < out[j].NestingLevel
})
return out
}
func (n Nodes) FirstWithNestingLevel(level int) Node {
for i := range n {
if n[i].NestingLevel == level {
return n[i]
}
}
return Node{}
}
func (n Nodes) Reverse() Nodes {
out := make(Nodes, len(n))
for i := range n {
out[len(n)-1-i] = n[i]
}
return out
}
func (n Nodes) Texts() []string {
out := make([]string, len(n))
for i := range n {
out[i] = n[i].Text
}
return out
}
func (n Nodes) Labels() [][]string {
out := make([][]string, len(n))
for i := range n {
if n[i].Labels == nil {
out[i] = []string{}
} else {
out[i] = []string(n[i].Labels)
}
}
return out
}
func (n Nodes) UnionOfLabels() []string {
out := []string{}
seen := map[string]bool{}
for i := range n {
for _, label := range n[i].Labels {
if !seen[label] {
seen[label] = true
out = append(out, label)
}
}
}
return out
}
func (n Nodes) CodeLocations() []types.CodeLocation {
out := make([]types.CodeLocation, len(n))
for i := range n {
out[i] = n[i].CodeLocation
}
return out
}
func (n Nodes) BestTextFor(node Node) string {
if node.Text != "" {
return node.Text
}
parentNestingLevel := node.NestingLevel - 1
for i := range n {
if n[i].Text != "" && n[i].NestingLevel == parentNestingLevel {
return n[i].Text
}
}
return ""
}
func (n Nodes) ContainsNodeID(id uint) bool {
for i := range n {
if n[i].ID == id {
return true
}
}
return false
}
func (n Nodes) HasNodeMarkedPending() bool {
for i := range n {
if n[i].MarkedPending {
return true
}
}
return false
}
func (n Nodes) HasNodeMarkedFocus() bool {
for i := range n {
if n[i].MarkedFocus {
return true
}
}
return false
}
func (n Nodes) HasNodeMarkedSerial() bool {
for i := range n {
if n[i].MarkedSerial {
return true
}
}
return false
}
func (n Nodes) FirstNodeMarkedOrdered() Node {
for i := range n {
if n[i].MarkedOrdered {
return n[i]
}
}
return Node{}
}
func unrollInterfaceSlice(args interface{}) []interface{} {
v := reflect.ValueOf(args)
if v.Kind() != reflect.Slice {
return []interface{}{args}
}
out := []interface{}{}
for i := 0; i < v.Len(); i++ {
el := reflect.ValueOf(v.Index(i).Interface())
if el.Kind() == reflect.Slice && el.Type() != reflect.TypeOf(Labels{}) {
out = append(out, unrollInterfaceSlice(el.Interface())...)
} else {
out = append(out, v.Index(i).Interface())
}
}
return out
}