platform_build_soong/android/testing.go

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// Copyright 2017 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"
"path/filepath"
"regexp"
"sort"
"strings"
"sync"
"testing"
"github.com/google/blueprint"
"github.com/google/blueprint/proptools"
)
func NewTestContext(config Config) *TestContext {
namespaceExportFilter := func(namespace *Namespace) bool {
return true
}
nameResolver := NewNameResolver(namespaceExportFilter)
ctx := &TestContext{
Context: &Context{blueprint.NewContext(), config},
NameResolver: nameResolver,
}
ctx.SetNameInterface(nameResolver)
ctx.postDeps = append(ctx.postDeps, registerPathDepsMutator)
ctx.SetFs(ctx.config.fs)
if ctx.config.mockBpList != "" {
ctx.SetModuleListFile(ctx.config.mockBpList)
}
return ctx
}
var PrepareForTestWithArchMutator = GroupFixturePreparers(
// Configure architecture targets in the fixture config.
FixtureModifyConfig(modifyTestConfigToSupportArchMutator),
// Add the arch mutator to the context.
FixtureRegisterWithContext(func(ctx RegistrationContext) {
ctx.PreDepsMutators(registerArchMutator)
}),
)
var PrepareForTestWithDefaults = FixtureRegisterWithContext(func(ctx RegistrationContext) {
ctx.PreArchMutators(RegisterDefaultsPreArchMutators)
})
var PrepareForTestWithComponentsMutator = FixtureRegisterWithContext(func(ctx RegistrationContext) {
ctx.PreArchMutators(RegisterComponentsMutator)
})
var PrepareForTestWithPrebuilts = FixtureRegisterWithContext(RegisterPrebuiltMutators)
var PrepareForTestWithOverrides = FixtureRegisterWithContext(func(ctx RegistrationContext) {
ctx.PostDepsMutators(RegisterOverridePostDepsMutators)
})
// Test fixture preparer that will register most java build components.
//
// Singletons and mutators should only be added here if they are needed for a majority of java
// module types, otherwise they should be added under a separate preparer to allow them to be
// selected only when needed to reduce test execution time.
//
// Module types do not have much of an overhead unless they are used so this should include as many
// module types as possible. The exceptions are those module types that require mutators and/or
// singletons in order to function in which case they should be kept together in a separate
// preparer.
//
// The mutators in this group were chosen because they are needed by the vast majority of tests.
var PrepareForTestWithAndroidBuildComponents = GroupFixturePreparers(
// Sorted alphabetically as the actual order does not matter as tests automatically enforce the
// correct order.
PrepareForTestWithArchMutator,
PrepareForTestWithComponentsMutator,
PrepareForTestWithDefaults,
PrepareForTestWithFilegroup,
PrepareForTestWithOverrides,
PrepareForTestWithPackageModule,
PrepareForTestWithPrebuilts,
PrepareForTestWithVisibility,
)
// Prepares an integration test with all build components from the android package.
//
// This should only be used by tests that want to run with as much of the build enabled as possible.
var PrepareForIntegrationTestWithAndroid = GroupFixturePreparers(
PrepareForTestWithAndroidBuildComponents,
)
// Prepares a test that may be missing dependencies by setting allow_missing_dependencies to
// true.
var PrepareForTestWithAllowMissingDependencies = GroupFixturePreparers(
FixtureModifyProductVariables(func(variables FixtureProductVariables) {
variables.Allow_missing_dependencies = proptools.BoolPtr(true)
}),
FixtureModifyContext(func(ctx *TestContext) {
ctx.SetAllowMissingDependencies(true)
}),
)
func NewTestArchContext(config Config) *TestContext {
ctx := NewTestContext(config)
ctx.preDeps = append(ctx.preDeps, registerArchMutator)
return ctx
}
type TestContext struct {
*Context
preArch, preDeps, postDeps, finalDeps []RegisterMutatorFunc
bp2buildPreArch, bp2buildDeps, bp2buildMutators []RegisterMutatorFunc
NameResolver *NameResolver
// The list of pre-singletons and singletons registered for the test.
preSingletons, singletons sortableComponents
// The order in which the pre-singletons, mutators and singletons will be run in this test
// context; for debugging.
preSingletonOrder, mutatorOrder, singletonOrder []string
}
func (ctx *TestContext) PreArchMutators(f RegisterMutatorFunc) {
ctx.preArch = append(ctx.preArch, f)
}
func (ctx *TestContext) HardCodedPreArchMutators(f RegisterMutatorFunc) {
// Register mutator function as normal for testing.
ctx.PreArchMutators(f)
}
func (ctx *TestContext) PreDepsMutators(f RegisterMutatorFunc) {
ctx.preDeps = append(ctx.preDeps, f)
}
func (ctx *TestContext) PostDepsMutators(f RegisterMutatorFunc) {
ctx.postDeps = append(ctx.postDeps, f)
}
func (ctx *TestContext) FinalDepsMutators(f RegisterMutatorFunc) {
ctx.finalDeps = append(ctx.finalDeps, f)
}
// RegisterBp2BuildMutator registers a BazelTargetModule mutator for converting a module
// type to the equivalent Bazel target.
func (ctx *TestContext) RegisterBp2BuildMutator(moduleType string, m func(TopDownMutatorContext)) {
f := func(ctx RegisterMutatorsContext) {
ctx.TopDown(moduleType, m)
}
ctx.bp2buildMutators = append(ctx.bp2buildMutators, f)
}
// PreArchBp2BuildMutators adds mutators to be register for converting Android Blueprint modules
// into Bazel BUILD targets that should run prior to deps and conversion.
func (ctx *TestContext) PreArchBp2BuildMutators(f RegisterMutatorFunc) {
ctx.bp2buildPreArch = append(ctx.bp2buildPreArch, f)
}
// DepsBp2BuildMutators adds mutators to be register for converting Android Blueprint modules into
// Bazel BUILD targets that should run prior to conversion to resolve dependencies.
func (ctx *TestContext) DepsBp2BuildMutators(f RegisterMutatorFunc) {
ctx.bp2buildDeps = append(ctx.bp2buildDeps, f)
}
// registeredComponentOrder defines the order in which a sortableComponent type is registered at
// runtime and provides support for reordering the components registered for a test in the same
// way.
type registeredComponentOrder struct {
// The name of the component type, used for error messages.
componentType string
// The names of the registered components in the order in which they were registered.
namesInOrder []string
// Maps from the component name to its position in the runtime ordering.
namesToIndex map[string]int
// A function that defines the order between two named components that can be used to sort a slice
// of component names into the same order as they appear in namesInOrder.
less func(string, string) bool
}
// registeredComponentOrderFromExistingOrder takes an existing slice of sortableComponents and
// creates a registeredComponentOrder that contains a less function that can be used to sort a
// subset of that list of names so it is in the same order as the original sortableComponents.
func registeredComponentOrderFromExistingOrder(componentType string, existingOrder sortableComponents) registeredComponentOrder {
// Only the names from the existing order are needed for this so create a list of component names
// in the correct order.
namesInOrder := componentsToNames(existingOrder)
// Populate the map from name to position in the list.
nameToIndex := make(map[string]int)
for i, n := range namesInOrder {
nameToIndex[n] = i
}
// A function to use to map from a name to an index in the original order.
indexOf := func(name string) int {
index, ok := nameToIndex[name]
if !ok {
// Should never happen as tests that use components that are not known at runtime do not sort
// so should never use this function.
panic(fmt.Errorf("internal error: unknown %s %q should be one of %s", componentType, name, strings.Join(namesInOrder, ", ")))
}
return index
}
// The less function.
less := func(n1, n2 string) bool {
i1 := indexOf(n1)
i2 := indexOf(n2)
return i1 < i2
}
return registeredComponentOrder{
componentType: componentType,
namesInOrder: namesInOrder,
namesToIndex: nameToIndex,
less: less,
}
}
// componentsToNames maps from the slice of components to a slice of their names.
func componentsToNames(components sortableComponents) []string {
names := make([]string, len(components))
for i, c := range components {
names[i] = c.componentName()
}
return names
}
// enforceOrdering enforces the supplied components are in the same order as is defined in this
// object.
//
// If the supplied components contains any components that are not registered at runtime, i.e. test
// specific components, then it is impossible to sort them into an order that both matches the
// runtime and also preserves the implicit ordering defined in the test. In that case it will not
// sort the components, instead it will just check that the components are in the correct order.
//
// Otherwise, this will sort the supplied components in place.
func (o *registeredComponentOrder) enforceOrdering(components sortableComponents) {
// Check to see if the list of components contains any components that are
// not registered at runtime.
var unknownComponents []string
testOrder := componentsToNames(components)
for _, name := range testOrder {
if _, ok := o.namesToIndex[name]; !ok {
unknownComponents = append(unknownComponents, name)
break
}
}
// If the slice contains some unknown components then it is not possible to
// sort them into an order that matches the runtime while also preserving the
// order expected from the test, so in that case don't sort just check that
// the order of the known mutators does match.
if len(unknownComponents) > 0 {
// Check order.
o.checkTestOrder(testOrder, unknownComponents)
} else {
// Sort the components.
sort.Slice(components, func(i, j int) bool {
n1 := components[i].componentName()
n2 := components[j].componentName()
return o.less(n1, n2)
})
}
}
// checkTestOrder checks that the supplied testOrder matches the one defined by this object,
// panicking if it does not.
func (o *registeredComponentOrder) checkTestOrder(testOrder []string, unknownComponents []string) {
lastMatchingTest := -1
matchCount := 0
// Take a copy of the runtime order as it is modified during the comparison.
runtimeOrder := append([]string(nil), o.namesInOrder...)
componentType := o.componentType
for i, j := 0, 0; i < len(testOrder) && j < len(runtimeOrder); {
test := testOrder[i]
runtime := runtimeOrder[j]
if test == runtime {
testOrder[i] = test + fmt.Sprintf(" <-- matched with runtime %s %d", componentType, j)
runtimeOrder[j] = runtime + fmt.Sprintf(" <-- matched with test %s %d", componentType, i)
lastMatchingTest = i
i += 1
j += 1
matchCount += 1
} else if _, ok := o.namesToIndex[test]; !ok {
// The test component is not registered globally so assume it is the correct place, treat it
// as having matched and skip it.
i += 1
matchCount += 1
} else {
// Assume that the test list is in the same order as the runtime list but the runtime list
// contains some components that are not present in the tests. So, skip the runtime component
// to try and find the next one that matches the current test component.
j += 1
}
}
// If every item in the test order was either test specific or matched one in the runtime then
// it is in the correct order. Otherwise, it was not so fail.
if matchCount != len(testOrder) {
// The test component names were not all matched with a runtime component name so there must
// either be a component present in the test that is not present in the runtime or they must be
// in the wrong order.
testOrder[lastMatchingTest+1] = testOrder[lastMatchingTest+1] + " <--- unmatched"
panic(fmt.Errorf("the tests uses test specific components %q and so cannot be automatically sorted."+
" Unfortunately it uses %s components in the wrong order.\n"+
"test order:\n %s\n"+
"runtime order\n %s\n",
SortedUniqueStrings(unknownComponents),
componentType,
strings.Join(testOrder, "\n "),
strings.Join(runtimeOrder, "\n ")))
}
}
// registrationSorter encapsulates the information needed to ensure that the test mutators are
// registered, and thereby executed, in the same order as they are at runtime.
//
// It MUST be populated lazily AFTER all package initialization has been done otherwise it will
// only define the order for a subset of all the registered build components that are available for
// the packages being tested.
//
// e.g if this is initialized during say the cc package initialization then any tests run in the
// java package will not sort build components registered by the java package's init() functions.
type registrationSorter struct {
// Used to ensure that this is only created once.
once sync.Once
// The order of pre-singletons
preSingletonOrder registeredComponentOrder
// The order of mutators
mutatorOrder registeredComponentOrder
// The order of singletons
singletonOrder registeredComponentOrder
}
// populate initializes this structure from globally registered build components.
//
// Only the first call has any effect.
func (s *registrationSorter) populate() {
s.once.Do(func() {
// Create an ordering from the globally registered pre-singletons.
s.preSingletonOrder = registeredComponentOrderFromExistingOrder("pre-singleton", preSingletons)
// Created an ordering from the globally registered mutators.
globallyRegisteredMutators := collateGloballyRegisteredMutators()
s.mutatorOrder = registeredComponentOrderFromExistingOrder("mutator", globallyRegisteredMutators)
// Create an ordering from the globally registered singletons.
globallyRegisteredSingletons := collateGloballyRegisteredSingletons()
s.singletonOrder = registeredComponentOrderFromExistingOrder("singleton", globallyRegisteredSingletons)
})
}
// Provides support for enforcing the same order in which build components are registered globally
// to the order in which they are registered during tests.
//
// MUST only be accessed via the globallyRegisteredComponentsOrder func.
var globalRegistrationSorter registrationSorter
// globallyRegisteredComponentsOrder returns the globalRegistrationSorter after ensuring it is
// correctly populated.
func globallyRegisteredComponentsOrder() *registrationSorter {
globalRegistrationSorter.populate()
return &globalRegistrationSorter
}
func (ctx *TestContext) Register() {
globalOrder := globallyRegisteredComponentsOrder()
// Ensure that the pre-singletons used in the test are in the same order as they are used at
// runtime.
globalOrder.preSingletonOrder.enforceOrdering(ctx.preSingletons)
ctx.preSingletons.registerAll(ctx.Context)
mutators := collateRegisteredMutators(ctx.preArch, ctx.preDeps, ctx.postDeps, ctx.finalDeps)
// Ensure that the mutators used in the test are in the same order as they are used at runtime.
globalOrder.mutatorOrder.enforceOrdering(mutators)
mutators.registerAll(ctx.Context)
// Register the env singleton with this context before sorting.
ctx.RegisterSingletonType("env", EnvSingleton)
// Ensure that the singletons used in the test are in the same order as they are used at runtime.
globalOrder.singletonOrder.enforceOrdering(ctx.singletons)
ctx.singletons.registerAll(ctx.Context)
// Save the sorted components order away to make them easy to access while debugging.
ctx.preSingletonOrder = componentsToNames(preSingletons)
ctx.mutatorOrder = componentsToNames(mutators)
ctx.singletonOrder = componentsToNames(singletons)
}
// RegisterForBazelConversion prepares a test context for bp2build conversion.
func (ctx *TestContext) RegisterForBazelConversion() {
RegisterMutatorsForBazelConversion(ctx.Context, ctx.bp2buildPreArch, ctx.bp2buildDeps, ctx.bp2buildMutators)
}
func (ctx *TestContext) ParseFileList(rootDir string, filePaths []string) (deps []string, errs []error) {
// This function adapts the old style ParseFileList calls that are spread throughout the tests
// to the new style that takes a config.
return ctx.Context.ParseFileList(rootDir, filePaths, ctx.config)
}
func (ctx *TestContext) ParseBlueprintsFiles(rootDir string) (deps []string, errs []error) {
// This function adapts the old style ParseBlueprintsFiles calls that are spread throughout the
// tests to the new style that takes a config.
return ctx.Context.ParseBlueprintsFiles(rootDir, ctx.config)
}
func (ctx *TestContext) RegisterModuleType(name string, factory ModuleFactory) {
ctx.Context.RegisterModuleType(name, ModuleFactoryAdaptor(factory))
}
func (ctx *TestContext) RegisterSingletonModuleType(name string, factory SingletonModuleFactory) {
s, m := SingletonModuleFactoryAdaptor(name, factory)
ctx.RegisterSingletonType(name, s)
ctx.RegisterModuleType(name, m)
}
func (ctx *TestContext) RegisterSingletonType(name string, factory SingletonFactory) {
ctx.singletons = append(ctx.singletons, newSingleton(name, factory))
}
func (ctx *TestContext) RegisterPreSingletonType(name string, factory SingletonFactory) {
ctx.preSingletons = append(ctx.preSingletons, newPreSingleton(name, factory))
}
func (ctx *TestContext) ModuleForTests(name, variant string) TestingModule {
var module Module
ctx.VisitAllModules(func(m blueprint.Module) {
if ctx.ModuleName(m) == name && ctx.ModuleSubDir(m) == variant {
module = m.(Module)
}
})
if module == nil {
// find all the modules that do exist
var allModuleNames []string
var allVariants []string
ctx.VisitAllModules(func(m blueprint.Module) {
allModuleNames = append(allModuleNames, ctx.ModuleName(m))
if ctx.ModuleName(m) == name {
allVariants = append(allVariants, ctx.ModuleSubDir(m))
}
})
sort.Strings(allModuleNames)
sort.Strings(allVariants)
if len(allVariants) == 0 {
panic(fmt.Errorf("failed to find module %q. All modules:\n %s",
name, strings.Join(allModuleNames, "\n ")))
} else {
panic(fmt.Errorf("failed to find module %q variant %q. All variants:\n %s",
name, variant, strings.Join(allVariants, "\n ")))
}
}
return TestingModule{module}
}
func (ctx *TestContext) ModuleVariantsForTests(name string) []string {
var variants []string
ctx.VisitAllModules(func(m blueprint.Module) {
if ctx.ModuleName(m) == name {
variants = append(variants, ctx.ModuleSubDir(m))
}
})
return variants
}
// SingletonForTests returns a TestingSingleton for the singleton registered with the given name.
func (ctx *TestContext) SingletonForTests(name string) TestingSingleton {
allSingletonNames := []string{}
for _, s := range ctx.Singletons() {
n := ctx.SingletonName(s)
if n == name {
return TestingSingleton{
singleton: s.(*singletonAdaptor).Singleton,
provider: s.(testBuildProvider),
}
}
allSingletonNames = append(allSingletonNames, n)
}
panic(fmt.Errorf("failed to find singleton %q."+
"\nall singletons: %v", name, allSingletonNames))
}
func (ctx *TestContext) Config() Config {
return ctx.config
}
type testBuildProvider interface {
BuildParamsForTests() []BuildParams
RuleParamsForTests() map[blueprint.Rule]blueprint.RuleParams
}
type TestingBuildParams struct {
BuildParams
RuleParams blueprint.RuleParams
}
func newTestingBuildParams(provider testBuildProvider, bparams BuildParams) TestingBuildParams {
return TestingBuildParams{
BuildParams: bparams,
RuleParams: provider.RuleParamsForTests()[bparams.Rule],
}
}
func maybeBuildParamsFromRule(provider testBuildProvider, rule string) (TestingBuildParams, []string) {
var searchedRules []string
for _, p := range provider.BuildParamsForTests() {
searchedRules = append(searchedRules, p.Rule.String())
if strings.Contains(p.Rule.String(), rule) {
return newTestingBuildParams(provider, p), searchedRules
}
}
return TestingBuildParams{}, searchedRules
}
func buildParamsFromRule(provider testBuildProvider, rule string) TestingBuildParams {
p, searchRules := maybeBuildParamsFromRule(provider, rule)
if p.Rule == nil {
panic(fmt.Errorf("couldn't find rule %q.\nall rules: %v", rule, searchRules))
}
return p
}
func maybeBuildParamsFromDescription(provider testBuildProvider, desc string) TestingBuildParams {
for _, p := range provider.BuildParamsForTests() {
if strings.Contains(p.Description, desc) {
return newTestingBuildParams(provider, p)
}
}
return TestingBuildParams{}
}
func buildParamsFromDescription(provider testBuildProvider, desc string) TestingBuildParams {
p := maybeBuildParamsFromDescription(provider, desc)
if p.Rule == nil {
panic(fmt.Errorf("couldn't find description %q", desc))
}
return p
}
func maybeBuildParamsFromOutput(provider testBuildProvider, file string) (TestingBuildParams, []string) {
var searchedOutputs []string
for _, p := range provider.BuildParamsForTests() {
outputs := append(WritablePaths(nil), p.Outputs...)
outputs = append(outputs, p.ImplicitOutputs...)
if p.Output != nil {
outputs = append(outputs, p.Output)
}
for _, f := range outputs {
if f.String() == file || f.Rel() == file {
return newTestingBuildParams(provider, p), nil
}
searchedOutputs = append(searchedOutputs, f.Rel())
}
}
return TestingBuildParams{}, searchedOutputs
}
func buildParamsFromOutput(provider testBuildProvider, file string) TestingBuildParams {
p, searchedOutputs := maybeBuildParamsFromOutput(provider, file)
if p.Rule == nil {
panic(fmt.Errorf("couldn't find output %q.\nall outputs: %v",
file, searchedOutputs))
}
return p
}
func allOutputs(provider testBuildProvider) []string {
var outputFullPaths []string
for _, p := range provider.BuildParamsForTests() {
outputs := append(WritablePaths(nil), p.Outputs...)
outputs = append(outputs, p.ImplicitOutputs...)
if p.Output != nil {
outputs = append(outputs, p.Output)
}
outputFullPaths = append(outputFullPaths, outputs.Strings()...)
}
return outputFullPaths
}
// TestingModule is wrapper around an android.Module that provides methods to find information about individual
// ctx.Build parameters for verification in tests.
type TestingModule struct {
module Module
}
// Module returns the Module wrapped by the TestingModule.
func (m TestingModule) Module() Module {
return m.module
}
// MaybeRule finds a call to ctx.Build with BuildParams.Rule set to a rule with the given name. Returns an empty
// BuildParams if no rule is found.
func (m TestingModule) MaybeRule(rule string) TestingBuildParams {
r, _ := maybeBuildParamsFromRule(m.module, rule)
return r
}
// Rule finds a call to ctx.Build with BuildParams.Rule set to a rule with the given name. Panics if no rule is found.
func (m TestingModule) Rule(rule string) TestingBuildParams {
return buildParamsFromRule(m.module, rule)
}
// MaybeDescription finds a call to ctx.Build with BuildParams.Description set to a the given string. Returns an empty
// BuildParams if no rule is found.
func (m TestingModule) MaybeDescription(desc string) TestingBuildParams {
return maybeBuildParamsFromDescription(m.module, desc)
}
// Description finds a call to ctx.Build with BuildParams.Description set to a the given string. Panics if no rule is
// found.
func (m TestingModule) Description(desc string) TestingBuildParams {
return buildParamsFromDescription(m.module, desc)
}
// MaybeOutput finds a call to ctx.Build with a BuildParams.Output or BuildParams.Outputs whose String() or Rel()
// value matches the provided string. Returns an empty BuildParams if no rule is found.
func (m TestingModule) MaybeOutput(file string) TestingBuildParams {
p, _ := maybeBuildParamsFromOutput(m.module, file)
return p
}
// Output finds a call to ctx.Build with a BuildParams.Output or BuildParams.Outputs whose String() or Rel()
// value matches the provided string. Panics if no rule is found.
func (m TestingModule) Output(file string) TestingBuildParams {
return buildParamsFromOutput(m.module, file)
}
// AllOutputs returns all 'BuildParams.Output's and 'BuildParams.Outputs's in their full path string forms.
func (m TestingModule) AllOutputs() []string {
return allOutputs(m.module)
}
// TestingSingleton is wrapper around an android.Singleton that provides methods to find information about individual
// ctx.Build parameters for verification in tests.
type TestingSingleton struct {
singleton Singleton
provider testBuildProvider
}
// Singleton returns the Singleton wrapped by the TestingSingleton.
func (s TestingSingleton) Singleton() Singleton {
return s.singleton
}
// MaybeRule finds a call to ctx.Build with BuildParams.Rule set to a rule with the given name. Returns an empty
// BuildParams if no rule is found.
func (s TestingSingleton) MaybeRule(rule string) TestingBuildParams {
r, _ := maybeBuildParamsFromRule(s.provider, rule)
return r
}
// Rule finds a call to ctx.Build with BuildParams.Rule set to a rule with the given name. Panics if no rule is found.
func (s TestingSingleton) Rule(rule string) TestingBuildParams {
return buildParamsFromRule(s.provider, rule)
}
// MaybeDescription finds a call to ctx.Build with BuildParams.Description set to a the given string. Returns an empty
// BuildParams if no rule is found.
func (s TestingSingleton) MaybeDescription(desc string) TestingBuildParams {
return maybeBuildParamsFromDescription(s.provider, desc)
}
// Description finds a call to ctx.Build with BuildParams.Description set to a the given string. Panics if no rule is
// found.
func (s TestingSingleton) Description(desc string) TestingBuildParams {
return buildParamsFromDescription(s.provider, desc)
}
// MaybeOutput finds a call to ctx.Build with a BuildParams.Output or BuildParams.Outputs whose String() or Rel()
// value matches the provided string. Returns an empty BuildParams if no rule is found.
func (s TestingSingleton) MaybeOutput(file string) TestingBuildParams {
p, _ := maybeBuildParamsFromOutput(s.provider, file)
return p
}
// Output finds a call to ctx.Build with a BuildParams.Output or BuildParams.Outputs whose String() or Rel()
// value matches the provided string. Panics if no rule is found.
func (s TestingSingleton) Output(file string) TestingBuildParams {
return buildParamsFromOutput(s.provider, file)
}
// AllOutputs returns all 'BuildParams.Output's and 'BuildParams.Outputs's in their full path string forms.
func (s TestingSingleton) AllOutputs() []string {
return allOutputs(s.provider)
}
func FailIfErrored(t *testing.T, errs []error) {
t.Helper()
if len(errs) > 0 {
for _, err := range errs {
t.Error(err)
}
t.FailNow()
}
}
// Fail if no errors that matched the regular expression were found.
//
// Returns true if a matching error was found, false otherwise.
func FailIfNoMatchingErrors(t *testing.T, pattern string, errs []error) bool {
t.Helper()
matcher, err := regexp.Compile(pattern)
if err != nil {
t.Fatalf("failed to compile regular expression %q because %s", pattern, err)
}
found := false
for _, err := range errs {
if matcher.FindStringIndex(err.Error()) != nil {
found = true
break
}
}
if !found {
t.Errorf("missing the expected error %q (checked %d error(s))", pattern, len(errs))
for i, err := range errs {
Reland: Deduplicate APEX variants that would build identically APEX variants that share the same SDK version and updatability almost always use identical command line arguments to build but with different intermediates directories. This causes unnecessary build time and disk space for duplicated work. Deduplicate APEX variants that would build identically. Create aliases from the per-APEX variations to the new shared variations so that the APEX modules can continue to depend on them via the APEX name as the variation. This has one significant change in behavior. Before this change, if an APEX had two libraries in its direct dependencies and one of those libraries depended on the other, and the second library had stubs, then the first library would depend on the implementation of the second library and not the stubs. After this change, if the first library is also present in a second APEX but the second library is not, then the common variant shared between the two APEXes would use the stubs, not the implementation. In a correctly configured set of build rules this change will be irrelevant, because if the compilation worked for the second APEX using stubs then it will work for the common variant using stubs. However, if an incorrect change to the build rules is made this could lead to confusing errors, as a previously-working common variant could suddenly stop building when a module is added to a new APEX without its dependencies that require implementation APIs to compile. This change reduces the number of modules in an AOSP arm64-userdebug build by 3% (52242 to 50586), reduces the number of variants of the libcutils module from 74 to 53, and reduces the number of variants of the massive libart[d] modules from 44 to 32. This relands I0529837476a253c32b3dfb98dcccf107427c742c with a fix to always mark permissions XML files of java_sdk_library modules as unique per apex since they contain the APEX filename, and a fix to UpdateUniqueApexVariationsForDeps to check ApexInfo.InApexes instead of DepIsInSameApex to check if two modules are in the same apex to account for a module that depends on another in a way that doesn't normally include the dependency in the APEX (e.g. a libs property), but the dependency is directly included in the APEX. Bug: 164216768 Test: go test ./build/soong/apex/... Change-Id: I2ae170601f764e5b88d0be2e0e6adc84e3a4d9cc
2020-08-12 03:17:01 +08:00
t.Errorf("errs[%d] = %q", i, err)
}
}
return found
}
func CheckErrorsAgainstExpectations(t *testing.T, errs []error, expectedErrorPatterns []string) {
t.Helper()
if expectedErrorPatterns == nil {
FailIfErrored(t, errs)
} else {
for _, expectedError := range expectedErrorPatterns {
FailIfNoMatchingErrors(t, expectedError, errs)
}
if len(errs) > len(expectedErrorPatterns) {
t.Errorf("additional errors found, expected %d, found %d",
len(expectedErrorPatterns), len(errs))
for i, expectedError := range expectedErrorPatterns {
t.Errorf("expectedErrors[%d] = %s", i, expectedError)
}
for i, err := range errs {
t.Errorf("errs[%d] = %s", i, err)
}
t.FailNow()
}
}
}
func SetKatiEnabledForTests(config Config) {
config.katiEnabled = true
}
func AndroidMkEntriesForTest(t *testing.T, ctx *TestContext, mod blueprint.Module) []AndroidMkEntries {
var p AndroidMkEntriesProvider
var ok bool
if p, ok = mod.(AndroidMkEntriesProvider); !ok {
t.Errorf("module does not implement AndroidMkEntriesProvider: " + mod.Name())
}
entriesList := p.AndroidMkEntries()
for i, _ := range entriesList {
entriesList[i].fillInEntries(ctx, mod)
}
return entriesList
}
func AndroidMkDataForTest(t *testing.T, ctx *TestContext, mod blueprint.Module) AndroidMkData {
var p AndroidMkDataProvider
var ok bool
if p, ok = mod.(AndroidMkDataProvider); !ok {
t.Errorf("module does not implement AndroidMkDataProvider: " + mod.Name())
}
data := p.AndroidMk()
data.fillInData(ctx, mod)
return data
}
// Normalize the path for testing.
//
// If the path is relative to the build directory then return the relative path
// to avoid tests having to deal with the dynamically generated build directory.
//
// Otherwise, return the supplied path as it is almost certainly a source path
// that is relative to the root of the source tree.
//
// The build and source paths should be distinguishable based on their contents.
//
// deprecated: use PathRelativeToTop instead as it handles make install paths and differentiates
// between output and source properly.
func NormalizePathForTesting(path Path) string {
Export dex implementation jars from prebuilt_apex Dexpreopt and boot jars package check all require access to dex implementation jars created for java_library and java_sdk_library. They were available when building from source but not when building from prebuilts, even though they are embedded within the .apex files that are referenced from prebuilt_apex. This changes adds support to prebuilt_apex to export the dex implementation jars and updates java_import to use those exported dex implementation jars. In a source build dexpreopt/boot jars package check access the apex (or platform) specific variant of a java_library, e.g. core-oj, from which it retrieves the dex implementation jar path. After this change in a prebuilt build dexpreopt/boot jars package check behave in the same way except in this case they retrieve the dex implementation jar path from the apex (or platform) specific variant of the java_import, e.g. core-oj. The work to export files from a `.apex` file for use by other modules is performed by a new `deapexer` module type. It is not used directly in an `Android.bp` file but instead is created implicitly by `prebuilt_apex`, In order to do that this contains the following changes: * Adds a new `dexapexer` module type to handle the exporting of files from the `.apex` file. * Adds an exported_java_libs property to prebuilt_apex to specify the set of libraries whose dex implementation jars need exporting. * Creates apex specific variants of the libraries listed in the exported_java_libs property. * Adds the set of exported files to the ApexInfo to make them available to the apex specific variants. * Prevents the prebuilt_apex variants from being merged together as they will not be compatible. * Modifies java_import to use the exported file for variants of a prebuilt_apex. * Adds a ninja rule to unpack (using deapexer) the contents of the prebuilt_apex's apex file, verify that the required files are present and make them available as outputs for other rules to use. * Some minor refactorings to support these changes. * Adds tests to cover prebuilt only, prebuilt with source preferred, and prebuilt preferred with source. Test: m nothing Bug: 171061220 Change-Id: Ic9bed81fb65b92f0d59f64c0bce168a9ed44cfac
2020-11-03 01:32:38 +08:00
if path == nil {
return "<nil path>"
}
p := path.String()
if w, ok := path.(WritablePath); ok {
rel, err := filepath.Rel(w.buildDir(), p)
if err != nil {
panic(err)
}
return rel
}
return p
}
// NormalizePathsForTesting creates a slice of strings where each string is the result of applying
// NormalizePathForTesting to the corresponding Path in the input slice.
//
// deprecated: use PathsRelativeToTop instead as it handles make install paths and differentiates
// between output and source properly.
func NormalizePathsForTesting(paths Paths) []string {
var result []string
for _, path := range paths {
relative := NormalizePathForTesting(path)
result = append(result, relative)
}
return result
}
// PathRelativeToTop returns a string representation of the path relative to a notional top
// directory.
//
// For a WritablePath it applies StringPathRelativeToTop to it, using the buildDir returned from the
// WritablePath's buildDir() method. For all other paths, i.e. source paths, that are already
// relative to the top it just returns their string representation.
func PathRelativeToTop(path Path) string {
if path == nil {
return "<nil path>"
}
p := path.String()
if w, ok := path.(WritablePath); ok {
buildDir := w.buildDir()
return StringPathRelativeToTop(buildDir, p)
}
return p
}
// PathsRelativeToTop creates a slice of strings where each string is the result of applying
// PathRelativeToTop to the corresponding Path in the input slice.
func PathsRelativeToTop(paths Paths) []string {
var result []string
for _, path := range paths {
relative := PathRelativeToTop(path)
result = append(result, relative)
}
return result
}
// StringPathRelativeToTop returns a string representation of the path relative to a notional top
// directory.
//
// A standard build has the following structure:
// ../top/
// out/ - make install files go here.
// out/soong - this is the buildDir passed to NewTestConfig()
// ... - the source files
//
// This function converts a path so that it appears relative to the ../top/ directory, i.e.
// * Make install paths, which have the pattern "buildDir/../<path>" are converted into the top
// relative path "out/<path>"
// * Soong install paths and other writable paths, which have the pattern "buildDir/<path>" are
// converted into the top relative path "out/soong/<path>".
// * Source paths are already relative to the top.
//
// This is provided for processing paths that have already been converted into a string, e.g. paths
// in AndroidMkEntries structures. As a result it needs to be supplied the soong output dir against
// which it can try and relativize paths. PathRelativeToTop must be used for process Path objects.
func StringPathRelativeToTop(soongOutDir string, path string) string {
// A relative path must be a source path so leave it as it is.
if !filepath.IsAbs(path) {
return path
}
// Check to see if the path is relative to the soong out dir.
rel, isRel, err := maybeRelErr(soongOutDir, path)
if err != nil {
panic(err)
}
if isRel {
// The path is in the soong out dir so indicate that in the relative path.
return filepath.Join("out/soong", rel)
}
// Check to see if the path is relative to the top level out dir.
outDir := filepath.Dir(soongOutDir)
rel, isRel, err = maybeRelErr(outDir, path)
if err != nil {
panic(err)
}
if isRel {
// The path is in the out dir so indicate that in the relative path.
return filepath.Join("out", rel)
}
// This should never happen.
panic(fmt.Errorf("internal error: absolute path %s is not relative to the out dir %s", path, outDir))
}
// StringPathsRelativeToTop creates a slice of strings where each string is the result of applying
// StringPathRelativeToTop to the corresponding string path in the input slice.
//
// This is provided for processing paths that have already been converted into a string, e.g. paths
// in AndroidMkEntries structures. As a result it needs to be supplied the soong output dir against
// which it can try and relativize paths. PathsRelativeToTop must be used for process Paths objects.
func StringPathsRelativeToTop(soongOutDir string, paths []string) []string {
var result []string
for _, path := range paths {
relative := StringPathRelativeToTop(soongOutDir, path)
result = append(result, relative)
}
return result
}