syncthing/vendor/github.com/onsi/ginkgo/ginkgo_dsl.go
Jakob Borg 65aaa607ab Use Go 1.5 vendoring instead of Godeps
Change made by:

- running "gvt fetch" on each of the packages mentioned in
  Godeps/Godeps.json
- `rm -rf Godeps`
- tweaking the build scripts to not mention Godeps
- tweaking the build scripts to test `./lib/...`, `./cmd/...` explicitly
  (to avoid testing vendor)
- tweaking the build scripts to not juggle GOPATH for Godeps and instead
  set GO15VENDOREXPERIMENT.

This also results in some updated packages at the same time I bet.

Building with Go 1.3 and 1.4 still *works* but won't use our vendored
dependencies - the user needs to have the actual packages in their
GOPATH then, which they'll get with a normal "go get". Building with Go
1.6+ will get our vendored dependencies by default even when not using
our build script, which is nice.

By doing this we gain some freedom in that we can pick and choose
manually what to include in vendor, as it's not based on just dependency
analysis of our own code. This is also a risk as we might pick up
dependencies we are unaware of, as the build may work locally with those
packages present in GOPATH. On the other hand the build server will
detect this as it has no packages in it's GOPATH beyond what is included
in the repo.

Recommended tool to manage dependencies is github.com/FiloSottile/gvt.
2016-03-05 21:21:24 +01:00

559 lines
21 KiB
Go

/*
Ginkgo is a BDD-style testing framework for Golang
The godoc documentation describes Ginkgo's API. More comprehensive documentation (with examples!) is available at http://onsi.github.io/ginkgo/
Ginkgo's preferred matcher library is [Gomega](http://github.com/onsi/gomega)
Ginkgo on Github: http://github.com/onsi/ginkgo
Ginkgo is MIT-Licensed
*/
package ginkgo
import (
"flag"
"fmt"
"io"
"net/http"
"os"
"strings"
"time"
"github.com/onsi/ginkgo/config"
"github.com/onsi/ginkgo/internal/codelocation"
"github.com/onsi/ginkgo/internal/failer"
"github.com/onsi/ginkgo/internal/remote"
"github.com/onsi/ginkgo/internal/suite"
"github.com/onsi/ginkgo/internal/testingtproxy"
"github.com/onsi/ginkgo/internal/writer"
"github.com/onsi/ginkgo/reporters"
"github.com/onsi/ginkgo/reporters/stenographer"
"github.com/onsi/ginkgo/types"
)
const GINKGO_VERSION = config.VERSION
const GINKGO_PANIC = `
Your test failed.
Ginkgo panics to prevent subsequent assertions from running.
Normally Ginkgo rescues this panic so you shouldn't see it.
But, if you make an assertion in a goroutine, Ginkgo can't capture the panic.
To circumvent this, you should call
defer GinkgoRecover()
at the top of the goroutine that caused this panic.
`
const defaultTimeout = 1
var globalSuite *suite.Suite
var globalFailer *failer.Failer
func init() {
config.Flags(flag.CommandLine, "ginkgo", true)
GinkgoWriter = writer.New(os.Stdout)
globalFailer = failer.New()
globalSuite = suite.New(globalFailer)
}
//GinkgoWriter implements an io.Writer
//When running in verbose mode any writes to GinkgoWriter will be immediately printed
//to stdout. Otherwise, GinkgoWriter will buffer any writes produced during the current test and flush them to screen
//only if the current test fails.
var GinkgoWriter io.Writer
//The interface by which Ginkgo receives *testing.T
type GinkgoTestingT interface {
Fail()
}
//GinkgoParallelNode returns the parallel node number for the current ginkgo process
//The node number is 1-indexed
func GinkgoParallelNode() int {
return config.GinkgoConfig.ParallelNode
}
//Some matcher libraries or legacy codebases require a *testing.T
//GinkgoT implements an interface analogous to *testing.T and can be used if
//the library in question accepts *testing.T through an interface
//
// For example, with testify:
// assert.Equal(GinkgoT(), 123, 123, "they should be equal")
//
// Or with gomock:
// gomock.NewController(GinkgoT())
//
// GinkgoT() takes an optional offset argument that can be used to get the
// correct line number associated with the failure.
func GinkgoT(optionalOffset ...int) GinkgoTInterface {
offset := 3
if len(optionalOffset) > 0 {
offset = optionalOffset[0]
}
return testingtproxy.New(GinkgoWriter, Fail, offset)
}
//The interface returned by GinkgoT(). This covers most of the methods
//in the testing package's T.
type GinkgoTInterface interface {
Fail()
Error(args ...interface{})
Errorf(format string, args ...interface{})
FailNow()
Fatal(args ...interface{})
Fatalf(format string, args ...interface{})
Log(args ...interface{})
Logf(format string, args ...interface{})
Failed() bool
Parallel()
Skip(args ...interface{})
Skipf(format string, args ...interface{})
SkipNow()
Skipped() bool
}
//Custom Ginkgo test reporters must implement the Reporter interface.
//
//The custom reporter is passed in a SuiteSummary when the suite begins and ends,
//and a SpecSummary just before a spec begins and just after a spec ends
type Reporter reporters.Reporter
//Asynchronous specs are given a channel of the Done type. You must close or write to the channel
//to tell Ginkgo that your async test is done.
type Done chan<- interface{}
//GinkgoTestDescription represents the information about the current running test returned by CurrentGinkgoTestDescription
// FullTestText: a concatenation of ComponentTexts and the TestText
// ComponentTexts: a list of all texts for the Describes & Contexts leading up to the current test
// TestText: the text in the actual It or Measure node
// IsMeasurement: true if the current test is a measurement
// FileName: the name of the file containing the current test
// LineNumber: the line number for the current test
// Failed: if the current test has failed, this will be true (useful in an AfterEach)
type GinkgoTestDescription struct {
FullTestText string
ComponentTexts []string
TestText string
IsMeasurement bool
FileName string
LineNumber int
Failed bool
}
//CurrentGinkgoTestDescripton returns information about the current running test.
func CurrentGinkgoTestDescription() GinkgoTestDescription {
summary, ok := globalSuite.CurrentRunningSpecSummary()
if !ok {
return GinkgoTestDescription{}
}
subjectCodeLocation := summary.ComponentCodeLocations[len(summary.ComponentCodeLocations)-1]
return GinkgoTestDescription{
ComponentTexts: summary.ComponentTexts[1:],
FullTestText: strings.Join(summary.ComponentTexts[1:], " "),
TestText: summary.ComponentTexts[len(summary.ComponentTexts)-1],
IsMeasurement: summary.IsMeasurement,
FileName: subjectCodeLocation.FileName,
LineNumber: subjectCodeLocation.LineNumber,
Failed: summary.HasFailureState(),
}
}
//Measurement tests receive a Benchmarker.
//
//You use the Time() function to time how long the passed in body function takes to run
//You use the RecordValue() function to track arbitrary numerical measurements.
//The optional info argument is passed to the test reporter and can be used to
// provide the measurement data to a custom reporter with context.
//
//See http://onsi.github.io/ginkgo/#benchmark_tests for more details
type Benchmarker interface {
Time(name string, body func(), info ...interface{}) (elapsedTime time.Duration)
RecordValue(name string, value float64, info ...interface{})
}
//RunSpecs is the entry point for the Ginkgo test runner.
//You must call this within a Golang testing TestX(t *testing.T) function.
//
//To bootstrap a test suite you can use the Ginkgo CLI:
//
// ginkgo bootstrap
func RunSpecs(t GinkgoTestingT, description string) bool {
specReporters := []Reporter{buildDefaultReporter()}
return RunSpecsWithCustomReporters(t, description, specReporters)
}
//To run your tests with Ginkgo's default reporter and your custom reporter(s), replace
//RunSpecs() with this method.
func RunSpecsWithDefaultAndCustomReporters(t GinkgoTestingT, description string, specReporters []Reporter) bool {
specReporters = append([]Reporter{buildDefaultReporter()}, specReporters...)
return RunSpecsWithCustomReporters(t, description, specReporters)
}
//To run your tests with your custom reporter(s) (and *not* Ginkgo's default reporter), replace
//RunSpecs() with this method. Note that parallel tests will not work correctly without the default reporter
func RunSpecsWithCustomReporters(t GinkgoTestingT, description string, specReporters []Reporter) bool {
writer := GinkgoWriter.(*writer.Writer)
writer.SetStream(config.DefaultReporterConfig.Verbose)
reporters := make([]reporters.Reporter, len(specReporters))
for i, reporter := range specReporters {
reporters[i] = reporter
}
passed, hasFocusedTests := globalSuite.Run(t, description, reporters, writer, config.GinkgoConfig)
if passed && hasFocusedTests {
fmt.Println("PASS | FOCUSED")
os.Exit(types.GINKGO_FOCUS_EXIT_CODE)
}
return passed
}
func buildDefaultReporter() Reporter {
remoteReportingServer := config.GinkgoConfig.StreamHost
if remoteReportingServer == "" {
stenographer := stenographer.New(!config.DefaultReporterConfig.NoColor)
return reporters.NewDefaultReporter(config.DefaultReporterConfig, stenographer)
} else {
return remote.NewForwardingReporter(remoteReportingServer, &http.Client{}, remote.NewOutputInterceptor())
}
}
//Skip notifies Ginkgo that the current spec should be skipped.
func Skip(message string, callerSkip ...int) {
skip := 0
if len(callerSkip) > 0 {
skip = callerSkip[0]
}
globalFailer.Skip(message, codelocation.New(skip+1))
panic(GINKGO_PANIC)
}
//Fail notifies Ginkgo that the current spec has failed. (Gomega will call Fail for you automatically when an assertion fails.)
func Fail(message string, callerSkip ...int) {
skip := 0
if len(callerSkip) > 0 {
skip = callerSkip[0]
}
globalFailer.Fail(message, codelocation.New(skip+1))
panic(GINKGO_PANIC)
}
//GinkgoRecover should be deferred at the top of any spawned goroutine that (may) call `Fail`
//Since Gomega assertions call fail, you should throw a `defer GinkgoRecover()` at the top of any goroutine that
//calls out to Gomega
//
//Here's why: Ginkgo's `Fail` method records the failure and then panics to prevent
//further assertions from running. This panic must be recovered. Ginkgo does this for you
//if the panic originates in a Ginkgo node (an It, BeforeEach, etc...)
//
//Unfortunately, if a panic originates on a goroutine *launched* from one of these nodes there's no
//way for Ginkgo to rescue the panic. To do this, you must remember to `defer GinkgoRecover()` at the top of such a goroutine.
func GinkgoRecover() {
e := recover()
if e != nil {
globalFailer.Panic(codelocation.New(1), e)
}
}
//Describe blocks allow you to organize your specs. A Describe block can contain any number of
//BeforeEach, AfterEach, JustBeforeEach, It, and Measurement blocks.
//
//In addition you can nest Describe and Context blocks. Describe and Context blocks are functionally
//equivalent. The difference is purely semantic -- you typical Describe the behavior of an object
//or method and, within that Describe, outline a number of Contexts.
func Describe(text string, body func()) bool {
globalSuite.PushContainerNode(text, body, types.FlagTypeNone, codelocation.New(1))
return true
}
//You can focus the tests within a describe block using FDescribe
func FDescribe(text string, body func()) bool {
globalSuite.PushContainerNode(text, body, types.FlagTypeFocused, codelocation.New(1))
return true
}
//You can mark the tests within a describe block as pending using PDescribe
func PDescribe(text string, body func()) bool {
globalSuite.PushContainerNode(text, body, types.FlagTypePending, codelocation.New(1))
return true
}
//You can mark the tests within a describe block as pending using XDescribe
func XDescribe(text string, body func()) bool {
globalSuite.PushContainerNode(text, body, types.FlagTypePending, codelocation.New(1))
return true
}
//Context blocks allow you to organize your specs. A Context block can contain any number of
//BeforeEach, AfterEach, JustBeforeEach, It, and Measurement blocks.
//
//In addition you can nest Describe and Context blocks. Describe and Context blocks are functionally
//equivalent. The difference is purely semantic -- you typical Describe the behavior of an object
//or method and, within that Describe, outline a number of Contexts.
func Context(text string, body func()) bool {
globalSuite.PushContainerNode(text, body, types.FlagTypeNone, codelocation.New(1))
return true
}
//You can focus the tests within a describe block using FContext
func FContext(text string, body func()) bool {
globalSuite.PushContainerNode(text, body, types.FlagTypeFocused, codelocation.New(1))
return true
}
//You can mark the tests within a describe block as pending using PContext
func PContext(text string, body func()) bool {
globalSuite.PushContainerNode(text, body, types.FlagTypePending, codelocation.New(1))
return true
}
//You can mark the tests within a describe block as pending using XContext
func XContext(text string, body func()) bool {
globalSuite.PushContainerNode(text, body, types.FlagTypePending, codelocation.New(1))
return true
}
//It blocks contain your test code and assertions. You cannot nest any other Ginkgo blocks
//within an It block.
//
//Ginkgo will normally run It blocks synchronously. To perform asynchronous tests, pass a
//function that accepts a Done channel. When you do this, you can also provide an optional timeout.
func It(text string, body interface{}, timeout ...float64) bool {
globalSuite.PushItNode(text, body, types.FlagTypeNone, codelocation.New(1), parseTimeout(timeout...))
return true
}
//You can focus individual Its using FIt
func FIt(text string, body interface{}, timeout ...float64) bool {
globalSuite.PushItNode(text, body, types.FlagTypeFocused, codelocation.New(1), parseTimeout(timeout...))
return true
}
//You can mark Its as pending using PIt
func PIt(text string, _ ...interface{}) bool {
globalSuite.PushItNode(text, func() {}, types.FlagTypePending, codelocation.New(1), 0)
return true
}
//You can mark Its as pending using XIt
func XIt(text string, _ ...interface{}) bool {
globalSuite.PushItNode(text, func() {}, types.FlagTypePending, codelocation.New(1), 0)
return true
}
//Specify blocks are aliases for It blocks and allow for more natural wording in situations
//which "It" does not fit into a natural sentence flow. All the same protocols apply for Specify blocks
//which apply to It blocks.
func Specify(text string, body interface{}, timeout ...float64) bool {
return It(text, body, timeout...)
}
//You can focus individual Specifys using FSpecify
func FSpecify(text string, body interface{}, timeout ...float64) bool {
return FIt(text, body, timeout...)
}
//You can mark Specifys as pending using PSpecify
func PSpecify(text string, is ...interface{}) bool {
return PIt(text, is...)
}
//You can mark Specifys as pending using XSpecify
func XSpecify(text string, is ...interface{}) bool {
return XIt(text, is...)
}
//By allows you to better document large Its.
//
//Generally you should try to keep your Its short and to the point. This is not always possible, however,
//especially in the context of integration tests that capture a particular workflow.
//
//By allows you to document such flows. By must be called within a runnable node (It, BeforeEach, Measure, etc...)
//By will simply log the passed in text to the GinkgoWriter. If By is handed a function it will immediately run the function.
func By(text string, callbacks ...func()) {
preamble := "\x1b[1mSTEP\x1b[0m"
if config.DefaultReporterConfig.NoColor {
preamble = "STEP"
}
fmt.Fprintln(GinkgoWriter, preamble+": "+text)
if len(callbacks) == 1 {
callbacks[0]()
}
if len(callbacks) > 1 {
panic("just one callback per By, please")
}
}
//Measure blocks run the passed in body function repeatedly (determined by the samples argument)
//and accumulate metrics provided to the Benchmarker by the body function.
//
//The body function must have the signature:
// func(b Benchmarker)
func Measure(text string, body interface{}, samples int) bool {
globalSuite.PushMeasureNode(text, body, types.FlagTypeNone, codelocation.New(1), samples)
return true
}
//You can focus individual Measures using FMeasure
func FMeasure(text string, body interface{}, samples int) bool {
globalSuite.PushMeasureNode(text, body, types.FlagTypeFocused, codelocation.New(1), samples)
return true
}
//You can mark Maeasurements as pending using PMeasure
func PMeasure(text string, _ ...interface{}) bool {
globalSuite.PushMeasureNode(text, func(b Benchmarker) {}, types.FlagTypePending, codelocation.New(1), 0)
return true
}
//You can mark Maeasurements as pending using XMeasure
func XMeasure(text string, _ ...interface{}) bool {
globalSuite.PushMeasureNode(text, func(b Benchmarker) {}, types.FlagTypePending, codelocation.New(1), 0)
return true
}
//BeforeSuite blocks are run just once before any specs are run. When running in parallel, each
//parallel node process will call BeforeSuite.
//
//BeforeSuite blocks can be made asynchronous by providing a body function that accepts a Done channel
//
//You may only register *one* BeforeSuite handler per test suite. You typically do so in your bootstrap file at the top level.
func BeforeSuite(body interface{}, timeout ...float64) bool {
globalSuite.SetBeforeSuiteNode(body, codelocation.New(1), parseTimeout(timeout...))
return true
}
//AfterSuite blocks are *always* run after all the specs regardless of whether specs have passed or failed.
//Moreover, if Ginkgo receives an interrupt signal (^C) it will attempt to run the AfterSuite before exiting.
//
//When running in parallel, each parallel node process will call AfterSuite.
//
//AfterSuite blocks can be made asynchronous by providing a body function that accepts a Done channel
//
//You may only register *one* AfterSuite handler per test suite. You typically do so in your bootstrap file at the top level.
func AfterSuite(body interface{}, timeout ...float64) bool {
globalSuite.SetAfterSuiteNode(body, codelocation.New(1), parseTimeout(timeout...))
return true
}
//SynchronizedBeforeSuite blocks are primarily meant to solve the problem of setting up singleton external resources shared across
//nodes when running tests in parallel. For example, say you have a shared database that you can only start one instance of that
//must be used in your tests. When running in parallel, only one node should set up the database and all other nodes should wait
//until that node is done before running.
//
//SynchronizedBeforeSuite accomplishes this by taking *two* function arguments. The first is only run on parallel node #1. The second is
//run on all nodes, but *only* after the first function completes succesfully. Ginkgo also makes it possible to send data from the first function (on Node 1)
//to the second function (on all the other nodes).
//
//The functions have the following signatures. The first function (which only runs on node 1) has the signature:
//
// func() []byte
//
//or, to run asynchronously:
//
// func(done Done) []byte
//
//The byte array returned by the first function is then passed to the second function, which has the signature:
//
// func(data []byte)
//
//or, to run asynchronously:
//
// func(data []byte, done Done)
//
//Here's a simple pseudo-code example that starts a shared database on Node 1 and shares the database's address with the other nodes:
//
// var dbClient db.Client
// var dbRunner db.Runner
//
// var _ = SynchronizedBeforeSuite(func() []byte {
// dbRunner = db.NewRunner()
// err := dbRunner.Start()
// Ω(err).ShouldNot(HaveOccurred())
// return []byte(dbRunner.URL)
// }, func(data []byte) {
// dbClient = db.NewClient()
// err := dbClient.Connect(string(data))
// Ω(err).ShouldNot(HaveOccurred())
// })
func SynchronizedBeforeSuite(node1Body interface{}, allNodesBody interface{}, timeout ...float64) bool {
globalSuite.SetSynchronizedBeforeSuiteNode(
node1Body,
allNodesBody,
codelocation.New(1),
parseTimeout(timeout...),
)
return true
}
//SynchronizedAfterSuite blocks complement the SynchronizedBeforeSuite blocks in solving the problem of setting up
//external singleton resources shared across nodes when running tests in parallel.
//
//SynchronizedAfterSuite accomplishes this by taking *two* function arguments. The first runs on all nodes. The second runs only on parallel node #1
//and *only* after all other nodes have finished and exited. This ensures that node 1, and any resources it is running, remain alive until
//all other nodes are finished.
//
//Both functions have the same signature: either func() or func(done Done) to run asynchronously.
//
//Here's a pseudo-code example that complements that given in SynchronizedBeforeSuite. Here, SynchronizedAfterSuite is used to tear down the shared database
//only after all nodes have finished:
//
// var _ = SynchronizedAfterSuite(func() {
// dbClient.Cleanup()
// }, func() {
// dbRunner.Stop()
// })
func SynchronizedAfterSuite(allNodesBody interface{}, node1Body interface{}, timeout ...float64) bool {
globalSuite.SetSynchronizedAfterSuiteNode(
allNodesBody,
node1Body,
codelocation.New(1),
parseTimeout(timeout...),
)
return true
}
//BeforeEach blocks are run before It blocks. When multiple BeforeEach blocks are defined in nested
//Describe and Context blocks the outermost BeforeEach blocks are run first.
//
//Like It blocks, BeforeEach blocks can be made asynchronous by providing a body function that accepts
//a Done channel
func BeforeEach(body interface{}, timeout ...float64) bool {
globalSuite.PushBeforeEachNode(body, codelocation.New(1), parseTimeout(timeout...))
return true
}
//JustBeforeEach blocks are run before It blocks but *after* all BeforeEach blocks. For more details,
//read the [documentation](http://onsi.github.io/ginkgo/#separating_creation_and_configuration_)
//
//Like It blocks, BeforeEach blocks can be made asynchronous by providing a body function that accepts
//a Done channel
func JustBeforeEach(body interface{}, timeout ...float64) bool {
globalSuite.PushJustBeforeEachNode(body, codelocation.New(1), parseTimeout(timeout...))
return true
}
//AfterEach blocks are run after It blocks. When multiple AfterEach blocks are defined in nested
//Describe and Context blocks the innermost AfterEach blocks are run first.
//
//Like It blocks, AfterEach blocks can be made asynchronous by providing a body function that accepts
//a Done channel
func AfterEach(body interface{}, timeout ...float64) bool {
globalSuite.PushAfterEachNode(body, codelocation.New(1), parseTimeout(timeout...))
return true
}
func parseTimeout(timeout ...float64) time.Duration {
if len(timeout) == 0 {
return time.Duration(defaultTimeout * int64(time.Second))
} else {
return time.Duration(timeout[0] * float64(time.Second))
}
}