platform_build_soong/android/fixture.go
Paul Duffin 0fc6d32c82 Switch the namespace tests to fully use test fixtures
Indented the bp contents to make it easier to differentiate between
them and the directory in which they belong.

Bug: 181070625
Test: m nothing
Change-Id: Iae7495fb7c88769dc688006a41f4d21f57cf03b8
2022-05-11 17:30:58 +00:00

883 lines
30 KiB
Go

// Copyright 2021 Google Inc. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package android
import (
"fmt"
"strings"
"testing"
)
// Provides support for creating test fixtures on which tests can be run. Reduces duplication
// of test setup by allow tests to easily reuse setup code.
//
// Fixture
// =======
// These determine the environment within which a test can be run. Fixtures are mutable and are
// created and mutated by FixturePreparer instances. They are created by first creating a base
// Fixture (which is essentially empty) and then applying FixturePreparer instances to it to modify
// the environment.
//
// FixturePreparer
// ===============
// These are responsible for modifying a Fixture in preparation for it to run a test. Preparers are
// intended to be immutable and able to prepare multiple Fixture objects simultaneously without
// them sharing any data.
//
// They provide the basic capabilities for running tests too.
//
// FixturePreparers are only ever applied once per test fixture. Prior to application the list of
// FixturePreparers are flattened and deduped while preserving the order they first appear in the
// list. This makes it easy to reuse, group and combine FixturePreparers together.
//
// Each small self contained piece of test setup should be their own FixturePreparer. e.g.
// * A group of related modules.
// * A group of related mutators.
// * A combination of both.
// * Configuration.
//
// They should not overlap, e.g. the same module type should not be registered by different
// FixturePreparers as using them both would cause a build error. In that case the preparer should
// be split into separate parts and combined together using FixturePreparers(...).
//
// e.g. attempting to use AllPreparers in preparing a Fixture would break as it would attempt to
// register module bar twice:
// var Preparer1 = FixtureRegisterWithContext(RegisterModuleFooAndBar)
// var Preparer2 = FixtureRegisterWithContext(RegisterModuleBarAndBaz)
// var AllPreparers = GroupFixturePreparers(Preparer1, Preparer2)
//
// However, when restructured like this it would work fine:
// var PreparerFoo = FixtureRegisterWithContext(RegisterModuleFoo)
// var PreparerBar = FixtureRegisterWithContext(RegisterModuleBar)
// var PreparerBaz = FixtureRegisterWithContext(RegisterModuleBaz)
// var Preparer1 = GroupFixturePreparers(RegisterModuleFoo, RegisterModuleBar)
// var Preparer2 = GroupFixturePreparers(RegisterModuleBar, RegisterModuleBaz)
// var AllPreparers = GroupFixturePreparers(Preparer1, Preparer2)
//
// As after deduping and flattening AllPreparers would result in the following preparers being
// applied:
// 1. PreparerFoo
// 2. PreparerBar
// 3. PreparerBaz
//
// Preparers can be used for both integration and unit tests.
//
// Integration tests typically use all the module types, mutators and singletons that are available
// for that package to try and replicate the behavior of the runtime build as closely as possible.
// However, that realism comes at a cost of increased fragility (as they can be broken by changes in
// many different parts of the build) and also increased runtime, especially if they use lots of
// singletons and mutators.
//
// Unit tests on the other hand try and minimize the amount of code being tested which makes them
// less susceptible to changes elsewhere in the build and quick to run but at a cost of potentially
// not testing realistic scenarios.
//
// Supporting unit tests effectively require that preparers are available at the lowest granularity
// possible. Supporting integration tests effectively require that the preparers are organized into
// groups that provide all the functionality available.
//
// At least in terms of tests that check the behavior of build components via processing
// `Android.bp` there is no clear separation between a unit test and an integration test. Instead
// they vary from one end that tests a single module (e.g. filegroup) to the other end that tests a
// whole system of modules, mutators and singletons (e.g. apex + hiddenapi).
//
// TestResult
// ==========
// These are created by running tests in a Fixture and provide access to the Config and TestContext
// in which the tests were run.
//
// Example
// =======
//
// An exported preparer for use by other packages that need to use java modules.
//
// package java
// var PrepareForIntegrationTestWithJava = GroupFixturePreparers(
// android.PrepareForIntegrationTestWithAndroid,
// FixtureRegisterWithContext(RegisterAGroupOfRelatedModulesMutatorsAndSingletons),
// FixtureRegisterWithContext(RegisterAnotherGroupOfRelatedModulesMutatorsAndSingletons),
// ...
// )
//
// Some files to use in tests in the java package.
//
// var javaMockFS = android.MockFS{
// "api/current.txt": nil,
// "api/removed.txt": nil,
// ...
// }
//
// A package private preparer for use for testing java within the java package.
//
// var prepareForJavaTest = android.GroupFixturePreparers(
// PrepareForIntegrationTestWithJava,
// FixtureRegisterWithContext(func(ctx android.RegistrationContext) {
// ctx.RegisterModuleType("test_module", testModule)
// }),
// javaMockFS.AddToFixture(),
// ...
// }
//
// func TestJavaStuff(t *testing.T) {
// result := android.GroupFixturePreparers(
// prepareForJavaTest,
// android.FixtureWithRootAndroidBp(`java_library {....}`),
// android.MockFS{...}.AddToFixture(),
// ).RunTest(t)
// ... test result ...
// }
//
// package cc
// var PrepareForTestWithCC = android.GroupFixturePreparers(
// android.PrepareForArchMutator,
// android.prepareForPrebuilts,
// FixtureRegisterWithContext(RegisterRequiredBuildComponentsForTest),
// ...
// )
//
// package apex
//
// var PrepareForApex = GroupFixturePreparers(
// ...
// )
//
// Use modules and mutators from java, cc and apex. Any duplicate preparers (like
// android.PrepareForArchMutator) will be automatically deduped.
//
// var prepareForApexTest = android.GroupFixturePreparers(
// PrepareForJava,
// PrepareForCC,
// PrepareForApex,
// )
//
// A set of mock files to add to the mock file system.
type MockFS map[string][]byte
// Merge adds the extra entries from the supplied map to this one.
//
// Fails if the supplied map files with the same paths are present in both of them.
func (fs MockFS) Merge(extra map[string][]byte) {
for p, c := range extra {
validateFixtureMockFSPath(p)
if _, ok := fs[p]; ok {
panic(fmt.Errorf("attempted to add file %s to the mock filesystem but it already exists", p))
}
fs[p] = c
}
}
// Ensure that tests cannot add paths into the mock file system which would not be allowed in the
// runtime, e.g. absolute paths, paths relative to the 'out/' directory.
func validateFixtureMockFSPath(path string) {
// This uses validateSafePath rather than validatePath because the latter prevents adding files
// that include a $ but there are tests that allow files with a $ to be used, albeit only by
// globbing.
validatedPath, err := validateSafePath(path)
if err != nil {
panic(err)
}
// Make sure that the path is canonical.
if validatedPath != path {
panic(fmt.Errorf("path %q is not a canonical path, use %q instead", path, validatedPath))
}
if path == "out" || strings.HasPrefix(path, "out/") {
panic(fmt.Errorf("cannot add output path %q to the mock file system", path))
}
}
func (fs MockFS) AddToFixture() FixturePreparer {
return FixtureMergeMockFs(fs)
}
// FixtureCustomPreparer allows for the modification of any aspect of the fixture.
//
// This should only be used if one of the other more specific preparers are not suitable.
func FixtureCustomPreparer(mutator func(fixture Fixture)) FixturePreparer {
return newSimpleFixturePreparer(func(f *fixture) {
mutator(f)
})
}
// Modify the config
func FixtureModifyConfig(mutator func(config Config)) FixturePreparer {
return newSimpleFixturePreparer(func(f *fixture) {
mutator(f.config)
})
}
// Modify the config and context
func FixtureModifyConfigAndContext(mutator func(config Config, ctx *TestContext)) FixturePreparer {
return newSimpleFixturePreparer(func(f *fixture) {
mutator(f.config, f.ctx)
})
}
// Modify the context
func FixtureModifyContext(mutator func(ctx *TestContext)) FixturePreparer {
return newSimpleFixturePreparer(func(f *fixture) {
mutator(f.ctx)
})
}
func FixtureRegisterWithContext(registeringFunc func(ctx RegistrationContext)) FixturePreparer {
return FixtureModifyContext(func(ctx *TestContext) { registeringFunc(ctx) })
}
// Modify the mock filesystem
func FixtureModifyMockFS(mutator func(fs MockFS)) FixturePreparer {
return newSimpleFixturePreparer(func(f *fixture) {
mutator(f.mockFS)
// Make sure that invalid paths were not added to the mock filesystem.
for p, _ := range f.mockFS {
validateFixtureMockFSPath(p)
}
})
}
// Merge the supplied file system into the mock filesystem.
//
// Paths that already exist in the mock file system are overridden.
func FixtureMergeMockFs(mockFS MockFS) FixturePreparer {
return FixtureModifyMockFS(func(fs MockFS) {
fs.Merge(mockFS)
})
}
// Add a file to the mock filesystem
//
// Fail if the filesystem already contains a file with that path, use FixtureOverrideFile instead.
func FixtureAddFile(path string, contents []byte) FixturePreparer {
return FixtureModifyMockFS(func(fs MockFS) {
validateFixtureMockFSPath(path)
if _, ok := fs[path]; ok {
panic(fmt.Errorf("attempted to add file %s to the mock filesystem but it already exists, use FixtureOverride*File instead", path))
}
fs[path] = contents
})
}
// Add a text file to the mock filesystem
//
// Fail if the filesystem already contains a file with that path.
func FixtureAddTextFile(path string, contents string) FixturePreparer {
return FixtureAddFile(path, []byte(contents))
}
// Override a file in the mock filesystem
//
// If the file does not exist this behaves as FixtureAddFile.
func FixtureOverrideFile(path string, contents []byte) FixturePreparer {
return FixtureModifyMockFS(func(fs MockFS) {
fs[path] = contents
})
}
// Override a text file in the mock filesystem
//
// If the file does not exist this behaves as FixtureAddTextFile.
func FixtureOverrideTextFile(path string, contents string) FixturePreparer {
return FixtureOverrideFile(path, []byte(contents))
}
// Add the root Android.bp file with the supplied contents.
func FixtureWithRootAndroidBp(contents string) FixturePreparer {
return FixtureAddTextFile("Android.bp", contents)
}
// Merge some environment variables into the fixture.
func FixtureMergeEnv(env map[string]string) FixturePreparer {
return FixtureModifyConfig(func(config Config) {
for k, v := range env {
if k == "PATH" {
panic("Cannot set PATH environment variable")
}
config.env[k] = v
}
})
}
// Modify the env.
//
// Will panic if the mutator changes the PATH environment variable.
func FixtureModifyEnv(mutator func(env map[string]string)) FixturePreparer {
return FixtureModifyConfig(func(config Config) {
oldPath := config.env["PATH"]
mutator(config.env)
newPath := config.env["PATH"]
if newPath != oldPath {
panic(fmt.Errorf("Cannot change PATH environment variable from %q to %q", oldPath, newPath))
}
})
}
// Allow access to the product variables when preparing the fixture.
type FixtureProductVariables struct {
*productVariables
}
// Modify product variables.
func FixtureModifyProductVariables(mutator func(variables FixtureProductVariables)) FixturePreparer {
return FixtureModifyConfig(func(config Config) {
productVariables := FixtureProductVariables{&config.productVariables}
mutator(productVariables)
})
}
// PrepareForDebug_DO_NOT_SUBMIT puts the fixture into debug which will cause it to output its
// state before running the test.
//
// This must only be added temporarily to a test for local debugging and must be removed from the
// test before submitting.
var PrepareForDebug_DO_NOT_SUBMIT = newSimpleFixturePreparer(func(fixture *fixture) {
fixture.debug = true
})
// GroupFixturePreparers creates a composite FixturePreparer that is equivalent to applying each of
// the supplied FixturePreparer instances in order.
//
// Before preparing the fixture the list of preparers is flattened by replacing each
// instance of GroupFixturePreparers with its contents.
func GroupFixturePreparers(preparers ...FixturePreparer) FixturePreparer {
all := dedupAndFlattenPreparers(nil, preparers)
return newFixturePreparer(all)
}
// NullFixturePreparer is a preparer that does nothing.
var NullFixturePreparer = GroupFixturePreparers()
// OptionalFixturePreparer will return the supplied preparer if it is non-nil, otherwise it will
// return the NullFixturePreparer
func OptionalFixturePreparer(preparer FixturePreparer) FixturePreparer {
if preparer == nil {
return NullFixturePreparer
} else {
return preparer
}
}
// FixturePreparer provides the ability to create, modify and then run tests within a fixture.
type FixturePreparer interface {
// Return the flattened and deduped list of simpleFixturePreparer pointers.
list() []*simpleFixturePreparer
// Create a Fixture.
Fixture(t *testing.T) Fixture
// ExtendWithErrorHandler creates a new FixturePreparer that will use the supplied error handler
// to check the errors (may be 0) reported by the test.
//
// The default handlers is FixtureExpectsNoErrors which will fail the go test immediately if any
// errors are reported.
ExtendWithErrorHandler(errorHandler FixtureErrorHandler) FixturePreparer
// Run the test, checking any errors reported and returning a TestResult instance.
//
// Shorthand for Fixture(t).RunTest()
RunTest(t *testing.T) *TestResult
// Run the test with the supplied Android.bp file.
//
// preparer.RunTestWithBp(t, bp) is shorthand for
// android.GroupFixturePreparers(preparer, android.FixtureWithRootAndroidBp(bp)).RunTest(t)
RunTestWithBp(t *testing.T, bp string) *TestResult
// RunTestWithConfig is a temporary method added to help ease the migration of existing tests to
// the test fixture.
//
// In order to allow the Config object to be customized separately to the TestContext a lot of
// existing test code has `test...WithConfig` funcs that allow the Config object to be supplied
// from the test and then have the TestContext created and configured automatically. e.g.
// testCcWithConfig, testCcErrorWithConfig, testJavaWithConfig, etc.
//
// This method allows those methods to be migrated to use the test fixture pattern without
// requiring that every test that uses those methods be migrated at the same time. That allows
// those tests to benefit from correctness in the order of registration quickly.
//
// This method discards the config (along with its mock file system, product variables,
// environment, etc.) that may have been set up by FixturePreparers.
//
// deprecated
RunTestWithConfig(t *testing.T, config Config) *TestResult
}
// dedupAndFlattenPreparers removes any duplicates and flattens any composite FixturePreparer
// instances.
//
// base - a list of already flattened and deduped preparers that will be applied first before
// the list of additional preparers. Any duplicates of these in the additional preparers
// will be ignored.
//
// preparers - a list of additional unflattened, undeduped preparers that will be applied after the
// base preparers.
//
// Returns a deduped and flattened list of the preparers starting with the ones in base with any
// additional ones from the preparers list added afterwards.
func dedupAndFlattenPreparers(base []*simpleFixturePreparer, preparers []FixturePreparer) []*simpleFixturePreparer {
if len(preparers) == 0 {
return base
}
list := make([]*simpleFixturePreparer, len(base))
visited := make(map[*simpleFixturePreparer]struct{})
// Mark the already flattened and deduped preparers, if any, as having been seen so that
// duplicates of these in the additional preparers will be discarded. Add them to the output
// list.
for i, s := range base {
visited[s] = struct{}{}
list[i] = s
}
for _, p := range preparers {
for _, s := range p.list() {
if _, seen := visited[s]; !seen {
visited[s] = struct{}{}
list = append(list, s)
}
}
}
return list
}
// compositeFixturePreparer is a FixturePreparer created from a list of fixture preparers.
type compositeFixturePreparer struct {
baseFixturePreparer
// The flattened and deduped list of simpleFixturePreparer pointers encapsulated within this
// composite preparer.
preparers []*simpleFixturePreparer
}
func (c *compositeFixturePreparer) list() []*simpleFixturePreparer {
return c.preparers
}
func newFixturePreparer(preparers []*simpleFixturePreparer) FixturePreparer {
if len(preparers) == 1 {
return preparers[0]
}
p := &compositeFixturePreparer{
preparers: preparers,
}
p.initBaseFixturePreparer(p)
return p
}
// simpleFixturePreparer is a FixturePreparer that applies a function to a fixture.
type simpleFixturePreparer struct {
baseFixturePreparer
function func(fixture *fixture)
}
func (s *simpleFixturePreparer) list() []*simpleFixturePreparer {
return []*simpleFixturePreparer{s}
}
func newSimpleFixturePreparer(preparer func(fixture *fixture)) FixturePreparer {
p := &simpleFixturePreparer{function: preparer}
p.initBaseFixturePreparer(p)
return p
}
// FixtureErrorHandler determines how to respond to errors reported by the code under test.
//
// Some possible responses:
// * Fail the test if any errors are reported, see FixtureExpectsNoErrors.
// * Fail the test if at least one error that matches a pattern is not reported see
// FixtureExpectsAtLeastOneErrorMatchingPattern
// * Fail the test if any unexpected errors are reported.
//
// Although at the moment all the error handlers are implemented as simply a wrapper around a
// function this is defined as an interface to allow future enhancements, e.g. provide different
// ways other than patterns to match an error and to combine handlers together.
type FixtureErrorHandler interface {
// CheckErrors checks the errors reported.
//
// The supplied result can be used to access the state of the code under test just as the main
// body of the test would but if any errors other than ones expected are reported the state may
// be indeterminate.
CheckErrors(t *testing.T, result *TestResult)
}
type simpleErrorHandler struct {
function func(t *testing.T, result *TestResult)
}
func (h simpleErrorHandler) CheckErrors(t *testing.T, result *TestResult) {
t.Helper()
h.function(t, result)
}
// The default fixture error handler.
//
// Will fail the test immediately if any errors are reported.
//
// If the test fails this handler will call `result.FailNow()` which will exit the goroutine within
// which the test is being run which means that the RunTest() method will not return.
var FixtureExpectsNoErrors = FixtureCustomErrorHandler(
func(t *testing.T, result *TestResult) {
t.Helper()
FailIfErrored(t, result.Errs)
},
)
// FixtureIgnoreErrors ignores any errors.
//
// If this is used then it is the responsibility of the test to check the TestResult.Errs does not
// contain any unexpected errors.
var FixtureIgnoreErrors = FixtureCustomErrorHandler(func(t *testing.T, result *TestResult) {
// Ignore the errors
})
// FixtureExpectsAtLeastOneMatchingError returns an error handler that will cause the test to fail
// if at least one error that matches the regular expression is not found.
//
// The test will be failed if:
// * No errors are reported.
// * One or more errors are reported but none match the pattern.
//
// The test will not fail if:
// * Multiple errors are reported that do not match the pattern as long as one does match.
//
// If the test fails this handler will call `result.FailNow()` which will exit the goroutine within
// which the test is being run which means that the RunTest() method will not return.
func FixtureExpectsAtLeastOneErrorMatchingPattern(pattern string) FixtureErrorHandler {
return FixtureCustomErrorHandler(func(t *testing.T, result *TestResult) {
t.Helper()
if !FailIfNoMatchingErrors(t, pattern, result.Errs) {
t.FailNow()
}
})
}
// FixtureExpectsOneErrorToMatchPerPattern returns an error handler that will cause the test to fail
// if there are any unexpected errors.
//
// The test will be failed if:
// * The number of errors reported does not exactly match the patterns.
// * One or more of the reported errors do not match a pattern.
// * No patterns are provided and one or more errors are reported.
//
// The test will not fail if:
// * One or more of the patterns does not match an error.
//
// If the test fails this handler will call `result.FailNow()` which will exit the goroutine within
// which the test is being run which means that the RunTest() method will not return.
func FixtureExpectsAllErrorsToMatchAPattern(patterns []string) FixtureErrorHandler {
return FixtureCustomErrorHandler(func(t *testing.T, result *TestResult) {
t.Helper()
CheckErrorsAgainstExpectations(t, result.Errs, patterns)
})
}
// FixtureExpectsOneErrorPattern returns an error handler that will cause the test to fail
// if there is more than one error or the error does not match the pattern.
//
// If the test fails this handler will call `result.FailNow()` which will exit the goroutine within
// which the test is being run which means that the RunTest() method will not return.
func FixtureExpectsOneErrorPattern(pattern string) FixtureErrorHandler {
return FixtureCustomErrorHandler(func(t *testing.T, result *TestResult) {
t.Helper()
CheckErrorsAgainstExpectations(t, result.Errs, []string{pattern})
})
}
// FixtureCustomErrorHandler creates a custom error handler
func FixtureCustomErrorHandler(function func(t *testing.T, result *TestResult)) FixtureErrorHandler {
return simpleErrorHandler{
function: function,
}
}
// Fixture defines the test environment.
type Fixture interface {
// Config returns the fixture's configuration.
Config() Config
// Context returns the fixture's test context.
Context() *TestContext
// MockFS returns the fixture's mock filesystem.
MockFS() MockFS
// Run the test, checking any errors reported and returning a TestResult instance.
RunTest() *TestResult
}
// Struct to allow TestResult to embed a *TestContext and allow call forwarding to its methods.
type testContext struct {
*TestContext
}
// The result of running a test.
type TestResult struct {
testContext
fixture *fixture
Config Config
// The errors that were reported during the test.
Errs []error
// The ninja deps is a list of the ninja files dependencies that were added by the modules and
// singletons via the *.AddNinjaFileDeps() methods.
NinjaDeps []string
}
func createFixture(t *testing.T, buildDir string, preparers []*simpleFixturePreparer) Fixture {
config := TestConfig(buildDir, nil, "", nil)
ctx := NewTestContext(config)
fixture := &fixture{
preparers: preparers,
t: t,
config: config,
ctx: ctx,
mockFS: make(MockFS),
// Set the default error handler.
errorHandler: FixtureExpectsNoErrors,
}
for _, preparer := range preparers {
preparer.function(fixture)
}
return fixture
}
type baseFixturePreparer struct {
self FixturePreparer
}
func (b *baseFixturePreparer) initBaseFixturePreparer(self FixturePreparer) {
b.self = self
}
func (b *baseFixturePreparer) Fixture(t *testing.T) Fixture {
return createFixture(t, t.TempDir(), b.self.list())
}
func (b *baseFixturePreparer) ExtendWithErrorHandler(errorHandler FixtureErrorHandler) FixturePreparer {
return GroupFixturePreparers(b.self, newSimpleFixturePreparer(func(fixture *fixture) {
fixture.errorHandler = errorHandler
}))
}
func (b *baseFixturePreparer) RunTest(t *testing.T) *TestResult {
t.Helper()
fixture := b.self.Fixture(t)
return fixture.RunTest()
}
func (b *baseFixturePreparer) RunTestWithBp(t *testing.T, bp string) *TestResult {
t.Helper()
return GroupFixturePreparers(b.self, FixtureWithRootAndroidBp(bp)).RunTest(t)
}
func (b *baseFixturePreparer) RunTestWithConfig(t *testing.T, config Config) *TestResult {
t.Helper()
// Create the fixture as normal.
fixture := b.self.Fixture(t).(*fixture)
// Discard the mock filesystem as otherwise that will override the one in the config.
fixture.mockFS = nil
// Replace the config with the supplied one in the fixture.
fixture.config = config
// Ditto with config derived information in the TestContext.
ctx := fixture.ctx
ctx.config = config
ctx.SetFs(ctx.config.fs)
if ctx.config.mockBpList != "" {
ctx.SetModuleListFile(ctx.config.mockBpList)
}
return fixture.RunTest()
}
type fixture struct {
// The preparers used to create this fixture.
preparers []*simpleFixturePreparer
// The gotest state of the go test within which this was created.
t *testing.T
// The configuration prepared for this fixture.
config Config
// The test context prepared for this fixture.
ctx *TestContext
// The mock filesystem prepared for this fixture.
mockFS MockFS
// The error handler used to check the errors, if any, that are reported.
errorHandler FixtureErrorHandler
// Debug mode status
debug bool
}
func (f *fixture) Config() Config {
return f.config
}
func (f *fixture) Context() *TestContext {
return f.ctx
}
func (f *fixture) MockFS() MockFS {
return f.mockFS
}
func (f *fixture) RunTest() *TestResult {
f.t.Helper()
// If in debug mode output the state of the fixture before running the test.
if f.debug {
f.outputDebugState()
}
ctx := f.ctx
// Do not use the fixture's mockFS to initialize the config's mock file system if it has been
// cleared by RunTestWithConfig.
if f.mockFS != nil {
// The TestConfig() method assumes that the mock filesystem is available when creating so
// creates the mock file system immediately. Similarly, the NewTestContext(Config) method
// assumes that the supplied Config's FileSystem has been properly initialized before it is
// called and so it takes its own reference to the filesystem. However, fixtures create the
// Config and TestContext early so they can be modified by preparers at which time the mockFS
// has not been populated (because it too is modified by preparers). So, this reinitializes the
// Config and TestContext's FileSystem using the now populated mockFS.
f.config.mockFileSystem("", f.mockFS)
ctx.SetFs(ctx.config.fs)
if ctx.config.mockBpList != "" {
ctx.SetModuleListFile(ctx.config.mockBpList)
}
}
ctx.Register()
var ninjaDeps []string
extraNinjaDeps, errs := ctx.ParseBlueprintsFiles("ignored")
if len(errs) == 0 {
ninjaDeps = append(ninjaDeps, extraNinjaDeps...)
extraNinjaDeps, errs = ctx.PrepareBuildActions(f.config)
if len(errs) == 0 {
ninjaDeps = append(ninjaDeps, extraNinjaDeps...)
}
}
result := &TestResult{
testContext: testContext{ctx},
fixture: f,
Config: f.config,
Errs: errs,
NinjaDeps: ninjaDeps,
}
f.errorHandler.CheckErrors(f.t, result)
return result
}
func (f *fixture) outputDebugState() {
fmt.Printf("Begin Fixture State for %s\n", f.t.Name())
if len(f.config.env) == 0 {
fmt.Printf(" Fixture Env is empty\n")
} else {
fmt.Printf(" Begin Env\n")
for k, v := range f.config.env {
fmt.Printf(" - %s=%s\n", k, v)
}
fmt.Printf(" End Env\n")
}
if len(f.mockFS) == 0 {
fmt.Printf(" Mock FS is empty\n")
} else {
fmt.Printf(" Begin Mock FS Contents\n")
for p, c := range f.mockFS {
if c == nil {
fmt.Printf("\n - %s: nil\n", p)
} else {
contents := string(c)
separator := " ========================================================================"
fmt.Printf(" - %s\n%s\n", p, separator)
for i, line := range strings.Split(contents, "\n") {
fmt.Printf(" %6d: %s\n", i+1, line)
}
fmt.Printf("%s\n", separator)
}
}
fmt.Printf(" End Mock FS Contents\n")
}
fmt.Printf("End Fixture State for %s\n", f.t.Name())
}
// NormalizePathForTesting removes the test invocation specific build directory from the supplied
// path.
//
// If the path is within the build directory (e.g. an OutputPath) then this returns the relative
// path to avoid tests having to deal with the dynamically generated build directory.
//
// Otherwise, this returns the supplied path as it is almost certainly a source path that is
// relative to the root of the source tree.
//
// Even though some information is removed from some paths and not others it should be possible to
// differentiate between them by the paths themselves, e.g. output paths will likely include
// ".intermediates" but source paths won't.
func (r *TestResult) NormalizePathForTesting(path Path) string {
pathContext := PathContextForTesting(r.Config)
pathAsString := path.String()
if rel, isRel := MaybeRel(pathContext, r.Config.SoongOutDir(), pathAsString); isRel {
return rel
}
return pathAsString
}
// NormalizePathsForTesting normalizes each path in the supplied list and returns their normalized
// forms.
func (r *TestResult) NormalizePathsForTesting(paths Paths) []string {
var result []string
for _, path := range paths {
result = append(result, r.NormalizePathForTesting(path))
}
return result
}
// Preparer will return a FixturePreparer encapsulating all the preparers used to create the fixture
// that produced this result.
//
// e.g. assuming that this result was created by running:
// GroupFixturePreparers(preparer1, preparer2, preparer3).RunTest(t)
//
// Then this method will be equivalent to running:
// GroupFixturePreparers(preparer1, preparer2, preparer3)
//
// This is intended for use by tests whose output is Android.bp files to verify that those files
// are valid, e.g. tests of the snapshots produced by the sdk module type.
func (r *TestResult) Preparer() FixturePreparer {
return newFixturePreparer(r.fixture.preparers)
}
// Module returns the module with the specific name and of the specified variant.
func (r *TestResult) Module(name string, variant string) Module {
return r.ModuleForTests(name, variant).Module()
}