ceph-csi/vendor/github.com/onsi/gomega/gomega_dsl.go
Humble Chirammal 3af1e26d7c Update to kube v1.17
Signed-off-by: Humble Chirammal <hchiramm@redhat.com>
2020-01-17 12:06:02 +00:00

435 lines
18 KiB
Go

/*
Gomega is the Ginkgo BDD-style testing framework's preferred matcher library.
The godoc documentation describes Gomega's API. More comprehensive documentation (with examples!) is available at http://onsi.github.io/gomega/
Gomega on Github: http://github.com/onsi/gomega
Learn more about Ginkgo online: http://onsi.github.io/ginkgo
Ginkgo on Github: http://github.com/onsi/ginkgo
Gomega is MIT-Licensed
*/
package gomega
import (
"fmt"
"reflect"
"time"
"github.com/onsi/gomega/internal/assertion"
"github.com/onsi/gomega/internal/asyncassertion"
"github.com/onsi/gomega/internal/testingtsupport"
"github.com/onsi/gomega/types"
)
const GOMEGA_VERSION = "1.8.1"
const nilFailHandlerPanic = `You are trying to make an assertion, but Gomega's fail handler is nil.
If you're using Ginkgo then you probably forgot to put your assertion in an It().
Alternatively, you may have forgotten to register a fail handler with RegisterFailHandler() or RegisterTestingT().
Depending on your vendoring solution you may be inadvertently importing gomega and subpackages (e.g. ghhtp, gexec,...) from different locations.
`
var globalFailWrapper *types.GomegaFailWrapper
var defaultEventuallyTimeout = time.Second
var defaultEventuallyPollingInterval = 10 * time.Millisecond
var defaultConsistentlyDuration = 100 * time.Millisecond
var defaultConsistentlyPollingInterval = 10 * time.Millisecond
// RegisterFailHandler connects Ginkgo to Gomega. When a matcher fails
// the fail handler passed into RegisterFailHandler is called.
func RegisterFailHandler(handler types.GomegaFailHandler) {
RegisterFailHandlerWithT(testingtsupport.EmptyTWithHelper{}, handler)
}
// RegisterFailHandlerWithT ensures that the given types.TWithHelper and fail handler
// are used globally.
func RegisterFailHandlerWithT(t types.TWithHelper, handler types.GomegaFailHandler) {
if handler == nil {
globalFailWrapper = nil
return
}
globalFailWrapper = &types.GomegaFailWrapper{
Fail: handler,
TWithHelper: t,
}
}
// RegisterTestingT connects Gomega to Golang's XUnit style
// Testing.T tests. It is now deprecated and you should use NewWithT() instead.
//
// Legacy Documentation:
//
// You'll need to call this at the top of each XUnit style test:
//
// func TestFarmHasCow(t *testing.T) {
// RegisterTestingT(t)
//
// f := farm.New([]string{"Cow", "Horse"})
// Expect(f.HasCow()).To(BeTrue(), "Farm should have cow")
// }
//
// Note that this *testing.T is registered *globally* by Gomega (this is why you don't have to
// pass `t` down to the matcher itself). This means that you cannot run the XUnit style tests
// in parallel as the global fail handler cannot point to more than one testing.T at a time.
//
// NewWithT() does not have this limitation
//
// (As an aside: Ginkgo gets around this limitation by running parallel tests in different *processes*).
func RegisterTestingT(t types.GomegaTestingT) {
tWithHelper, hasHelper := t.(types.TWithHelper)
if !hasHelper {
RegisterFailHandler(testingtsupport.BuildTestingTGomegaFailWrapper(t).Fail)
return
}
RegisterFailHandlerWithT(tWithHelper, testingtsupport.BuildTestingTGomegaFailWrapper(t).Fail)
}
// InterceptGomegaFailures runs a given callback and returns an array of
// failure messages generated by any Gomega assertions within the callback.
//
// This is accomplished by temporarily replacing the *global* fail handler
// with a fail handler that simply annotates failures. The original fail handler
// is reset when InterceptGomegaFailures returns.
//
// This is most useful when testing custom matchers, but can also be used to check
// on a value using a Gomega assertion without causing a test failure.
func InterceptGomegaFailures(f func()) []string {
originalHandler := globalFailWrapper.Fail
failures := []string{}
RegisterFailHandler(func(message string, callerSkip ...int) {
failures = append(failures, message)
})
f()
RegisterFailHandler(originalHandler)
return failures
}
// Ω wraps an actual value allowing assertions to be made on it:
// Ω("foo").Should(Equal("foo"))
//
// If Ω is passed more than one argument it will pass the *first* argument to the matcher.
// All subsequent arguments will be required to be nil/zero.
//
// This is convenient if you want to make an assertion on a method/function that returns
// a value and an error - a common patter in Go.
//
// For example, given a function with signature:
// func MyAmazingThing() (int, error)
//
// Then:
// Ω(MyAmazingThing()).Should(Equal(3))
// Will succeed only if `MyAmazingThing()` returns `(3, nil)`
//
// Ω and Expect are identical
func Ω(actual interface{}, extra ...interface{}) Assertion {
return ExpectWithOffset(0, actual, extra...)
}
// Expect wraps an actual value allowing assertions to be made on it:
// Expect("foo").To(Equal("foo"))
//
// If Expect is passed more than one argument it will pass the *first* argument to the matcher.
// All subsequent arguments will be required to be nil/zero.
//
// This is convenient if you want to make an assertion on a method/function that returns
// a value and an error - a common patter in Go.
//
// For example, given a function with signature:
// func MyAmazingThing() (int, error)
//
// Then:
// Expect(MyAmazingThing()).Should(Equal(3))
// Will succeed only if `MyAmazingThing()` returns `(3, nil)`
//
// Expect and Ω are identical
func Expect(actual interface{}, extra ...interface{}) Assertion {
return ExpectWithOffset(0, actual, extra...)
}
// ExpectWithOffset wraps an actual value allowing assertions to be made on it:
// ExpectWithOffset(1, "foo").To(Equal("foo"))
//
// Unlike `Expect` and `Ω`, `ExpectWithOffset` takes an additional integer argument
// that is used to modify the call-stack offset when computing line numbers.
//
// This is most useful in helper functions that make assertions. If you want Gomega's
// error message to refer to the calling line in the test (as opposed to the line in the helper function)
// set the first argument of `ExpectWithOffset` appropriately.
func ExpectWithOffset(offset int, actual interface{}, extra ...interface{}) Assertion {
if globalFailWrapper == nil {
panic(nilFailHandlerPanic)
}
return assertion.New(actual, globalFailWrapper, offset, extra...)
}
// Eventually wraps an actual value allowing assertions to be made on it.
// The assertion is tried periodically until it passes or a timeout occurs.
//
// Both the timeout and polling interval are configurable as optional arguments:
// The first optional argument is the timeout
// The second optional argument is the polling interval
//
// Both intervals can either be specified as time.Duration, parsable duration strings or as floats/integers. In the
// last case they are interpreted as seconds.
//
// If Eventually is passed an actual that is a function taking no arguments and returning at least one value,
// then Eventually will call the function periodically and try the matcher against the function's first return value.
//
// Example:
//
// Eventually(func() int {
// return thingImPolling.Count()
// }).Should(BeNumerically(">=", 17))
//
// Note that this example could be rewritten:
//
// Eventually(thingImPolling.Count).Should(BeNumerically(">=", 17))
//
// If the function returns more than one value, then Eventually will pass the first value to the matcher and
// assert that all other values are nil/zero.
// This allows you to pass Eventually a function that returns a value and an error - a common pattern in Go.
//
// For example, consider a method that returns a value and an error:
// func FetchFromDB() (string, error)
//
// Then
// Eventually(FetchFromDB).Should(Equal("hasselhoff"))
//
// Will pass only if the the returned error is nil and the returned string passes the matcher.
//
// Eventually's default timeout is 1 second, and its default polling interval is 10ms
func Eventually(actual interface{}, intervals ...interface{}) AsyncAssertion {
return EventuallyWithOffset(0, actual, intervals...)
}
// EventuallyWithOffset operates like Eventually but takes an additional
// initial argument to indicate an offset in the call stack. This is useful when building helper
// functions that contain matchers. To learn more, read about `ExpectWithOffset`.
func EventuallyWithOffset(offset int, actual interface{}, intervals ...interface{}) AsyncAssertion {
if globalFailWrapper == nil {
panic(nilFailHandlerPanic)
}
timeoutInterval := defaultEventuallyTimeout
pollingInterval := defaultEventuallyPollingInterval
if len(intervals) > 0 {
timeoutInterval = toDuration(intervals[0])
}
if len(intervals) > 1 {
pollingInterval = toDuration(intervals[1])
}
return asyncassertion.New(asyncassertion.AsyncAssertionTypeEventually, actual, globalFailWrapper, timeoutInterval, pollingInterval, offset)
}
// Consistently wraps an actual value allowing assertions to be made on it.
// The assertion is tried periodically and is required to pass for a period of time.
//
// Both the total time and polling interval are configurable as optional arguments:
// The first optional argument is the duration that Consistently will run for
// The second optional argument is the polling interval
//
// Both intervals can either be specified as time.Duration, parsable duration strings or as floats/integers. In the
// last case they are interpreted as seconds.
//
// If Consistently is passed an actual that is a function taking no arguments and returning at least one value,
// then Consistently will call the function periodically and try the matcher against the function's first return value.
//
// If the function returns more than one value, then Consistently will pass the first value to the matcher and
// assert that all other values are nil/zero.
// This allows you to pass Consistently a function that returns a value and an error - a common pattern in Go.
//
// Consistently is useful in cases where you want to assert that something *does not happen* over a period of time.
// For example, you want to assert that a goroutine does *not* send data down a channel. In this case, you could:
//
// Consistently(channel).ShouldNot(Receive())
//
// Consistently's default duration is 100ms, and its default polling interval is 10ms
func Consistently(actual interface{}, intervals ...interface{}) AsyncAssertion {
return ConsistentlyWithOffset(0, actual, intervals...)
}
// ConsistentlyWithOffset operates like Consistnetly but takes an additional
// initial argument to indicate an offset in the call stack. This is useful when building helper
// functions that contain matchers. To learn more, read about `ExpectWithOffset`.
func ConsistentlyWithOffset(offset int, actual interface{}, intervals ...interface{}) AsyncAssertion {
if globalFailWrapper == nil {
panic(nilFailHandlerPanic)
}
timeoutInterval := defaultConsistentlyDuration
pollingInterval := defaultConsistentlyPollingInterval
if len(intervals) > 0 {
timeoutInterval = toDuration(intervals[0])
}
if len(intervals) > 1 {
pollingInterval = toDuration(intervals[1])
}
return asyncassertion.New(asyncassertion.AsyncAssertionTypeConsistently, actual, globalFailWrapper, timeoutInterval, pollingInterval, offset)
}
// SetDefaultEventuallyTimeout sets the default timeout duration for Eventually. Eventually will repeatedly poll your condition until it succeeds, or until this timeout elapses.
func SetDefaultEventuallyTimeout(t time.Duration) {
defaultEventuallyTimeout = t
}
// SetDefaultEventuallyPollingInterval sets the default polling interval for Eventually.
func SetDefaultEventuallyPollingInterval(t time.Duration) {
defaultEventuallyPollingInterval = t
}
// SetDefaultConsistentlyDuration sets the default duration for Consistently. Consistently will verify that your condition is satisfied for this long.
func SetDefaultConsistentlyDuration(t time.Duration) {
defaultConsistentlyDuration = t
}
// SetDefaultConsistentlyPollingInterval sets the default polling interval for Consistently.
func SetDefaultConsistentlyPollingInterval(t time.Duration) {
defaultConsistentlyPollingInterval = t
}
// AsyncAssertion is returned by Eventually and Consistently and polls the actual value passed into Eventually against
// the matcher passed to the Should and ShouldNot methods.
//
// Both Should and ShouldNot take a variadic optionalDescription argument.
// This argument allows you to make your failure messages more descriptive.
// If a single argument of type `func() string` is passed, this function will be lazily evaluated if a failure occurs
// and the returned string is used to annotate the failure message.
// Otherwise, this argument is passed on to fmt.Sprintf() and then used to annotate the failure message.
//
// Both Should and ShouldNot return a boolean that is true if the assertion passed and false if it failed.
//
// Example:
//
// Eventually(myChannel).Should(Receive(), "Something should have come down the pipe.")
// Consistently(myChannel).ShouldNot(Receive(), func() string { return "Nothing should have come down the pipe." })
type AsyncAssertion interface {
Should(matcher types.GomegaMatcher, optionalDescription ...interface{}) bool
ShouldNot(matcher types.GomegaMatcher, optionalDescription ...interface{}) bool
}
// GomegaAsyncAssertion is deprecated in favor of AsyncAssertion, which does not stutter.
type GomegaAsyncAssertion = AsyncAssertion
// Assertion is returned by Ω and Expect and compares the actual value to the matcher
// passed to the Should/ShouldNot and To/ToNot/NotTo methods.
//
// Typically Should/ShouldNot are used with Ω and To/ToNot/NotTo are used with Expect
// though this is not enforced.
//
// All methods take a variadic optionalDescription argument.
// This argument allows you to make your failure messages more descriptive.
// If a single argument of type `func() string` is passed, this function will be lazily evaluated if a failure occurs
// and the returned string is used to annotate the failure message.
// Otherwise, this argument is passed on to fmt.Sprintf() and then used to annotate the failure message.
//
// All methods return a bool that is true if the assertion passed and false if it failed.
//
// Example:
//
// Ω(farm.HasCow()).Should(BeTrue(), "Farm %v should have a cow", farm)
type Assertion interface {
Should(matcher types.GomegaMatcher, optionalDescription ...interface{}) bool
ShouldNot(matcher types.GomegaMatcher, optionalDescription ...interface{}) bool
To(matcher types.GomegaMatcher, optionalDescription ...interface{}) bool
ToNot(matcher types.GomegaMatcher, optionalDescription ...interface{}) bool
NotTo(matcher types.GomegaMatcher, optionalDescription ...interface{}) bool
}
// GomegaAssertion is deprecated in favor of Assertion, which does not stutter.
type GomegaAssertion = Assertion
// OmegaMatcher is deprecated in favor of the better-named and better-organized types.GomegaMatcher but sticks around to support existing code that uses it
type OmegaMatcher types.GomegaMatcher
// WithT wraps a *testing.T and provides `Expect`, `Eventually`, and `Consistently` methods. This allows you to leverage
// Gomega's rich ecosystem of matchers in standard `testing` test suites.
//
// Use `NewWithT` to instantiate a `WithT`
type WithT struct {
t types.GomegaTestingT
}
// GomegaWithT is deprecated in favor of gomega.WithT, which does not stutter.
type GomegaWithT = WithT
// NewWithT takes a *testing.T and returngs a `gomega.WithT` allowing you to use `Expect`, `Eventually`, and `Consistently` along with
// Gomega's rich ecosystem of matchers in standard `testing` test suits.
//
// func TestFarmHasCow(t *testing.T) {
// g := gomega.NewWithT(t)
//
// f := farm.New([]string{"Cow", "Horse"})
// g.Expect(f.HasCow()).To(BeTrue(), "Farm should have cow")
// }
func NewWithT(t types.GomegaTestingT) *WithT {
return &WithT{
t: t,
}
}
// NewGomegaWithT is deprecated in favor of gomega.NewWithT, which does not stutter.
func NewGomegaWithT(t types.GomegaTestingT) *GomegaWithT {
return NewWithT(t)
}
// Expect is used to make assertions. See documentation for Expect.
func (g *WithT) Expect(actual interface{}, extra ...interface{}) Assertion {
return assertion.New(actual, testingtsupport.BuildTestingTGomegaFailWrapper(g.t), 0, extra...)
}
// Eventually is used to make asynchronous assertions. See documentation for Eventually.
func (g *WithT) Eventually(actual interface{}, intervals ...interface{}) AsyncAssertion {
timeoutInterval := defaultEventuallyTimeout
pollingInterval := defaultEventuallyPollingInterval
if len(intervals) > 0 {
timeoutInterval = toDuration(intervals[0])
}
if len(intervals) > 1 {
pollingInterval = toDuration(intervals[1])
}
return asyncassertion.New(asyncassertion.AsyncAssertionTypeEventually, actual, testingtsupport.BuildTestingTGomegaFailWrapper(g.t), timeoutInterval, pollingInterval, 0)
}
// Consistently is used to make asynchronous assertions. See documentation for Consistently.
func (g *WithT) Consistently(actual interface{}, intervals ...interface{}) AsyncAssertion {
timeoutInterval := defaultConsistentlyDuration
pollingInterval := defaultConsistentlyPollingInterval
if len(intervals) > 0 {
timeoutInterval = toDuration(intervals[0])
}
if len(intervals) > 1 {
pollingInterval = toDuration(intervals[1])
}
return asyncassertion.New(asyncassertion.AsyncAssertionTypeConsistently, actual, testingtsupport.BuildTestingTGomegaFailWrapper(g.t), timeoutInterval, pollingInterval, 0)
}
func toDuration(input interface{}) time.Duration {
duration, ok := input.(time.Duration)
if ok {
return duration
}
value := reflect.ValueOf(input)
kind := reflect.TypeOf(input).Kind()
if reflect.Int <= kind && kind <= reflect.Int64 {
return time.Duration(value.Int()) * time.Second
} else if reflect.Uint <= kind && kind <= reflect.Uint64 {
return time.Duration(value.Uint()) * time.Second
} else if reflect.Float32 <= kind && kind <= reflect.Float64 {
return time.Duration(value.Float() * float64(time.Second))
} else if reflect.String == kind {
duration, err := time.ParseDuration(value.String())
if err != nil {
panic(fmt.Sprintf("%#v is not a valid parsable duration string.", input))
}
return duration
}
panic(fmt.Sprintf("%v is not a valid interval. Must be time.Duration, parsable duration string or a number.", input))
}