transition.go - platform/build/blueprint - Git at Google

 // Copyright 2024 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 blueprint

 import (
 	"fmt"
 	"slices"
 	"sort"
 )

 // TransitionMutator implements a top-down mechanism where a module tells its
 // direct dependencies what variation they should be built in but the dependency
 // has the final say.
 //
 // When implementing a transition mutator, one needs to implement four methods:
 //   - Split() that tells what variations a module has by itself
 //   - OutgoingTransition() where a module tells what it wants from its
 //     dependency
 //   - IncomingTransition() where a module has the final say about its own
 //     variation
 //   - Mutate() that changes the state of a module depending on its variation
 //
 // That the effective variation of module B when depended on by module A is the
 // composition the outgoing transition of module A and the incoming transition
 // of module B.
 //
 // The outgoing transition should not take the properties of the dependency into
 // account, only those of the module that depends on it. For this reason, the
 // dependency is not even passed into it as an argument. Likewise, the incoming
 // transition should not take the properties of the depending module into
 // account and is thus not informed about it. This makes for a nice
 // decomposition of the decision logic.
 //
 // A given transition mutator only affects its own variation; other variations
 // stay unchanged along the dependency edges.
 //
 // Soong makes sure that all modules are created in the desired variations and
 // that dependency edges are set up correctly. This ensures that "missing
 // variation" errors do not happen and allows for more flexible changes in the
 // value of the variation among dependency edges (as opposed to bottom-up
 // mutators where if module A in variation X depends on module B and module B
 // has that variation X, A must depend on variation X of B)
 //
 // The limited power of the context objects passed to individual mutators
 // methods also makes it more difficult to shoot oneself in the foot. Complete
 // safety is not guaranteed because no one prevents individual transition
 // mutators from mutating modules in illegal ways and for e.g. Split() or
 // Mutate() to run their own visitations of the transitive dependency of the
 // module and both of these are bad ideas, but it's better than no guardrails at
 // all.
 //
 // This model is pretty close to Bazel's configuration transitions. The mapping
 // between concepts in Soong and Bazel is as follows:
 //   - Module == configured target
 //   - Variant == configuration
 //   - Variation name == configuration flag
 //   - Variation == configuration flag value
 //   - Outgoing transition == attribute transition
 //   - Incoming transition == rule transition
 //
 // The Split() method does not have a Bazel equivalent and Bazel split
 // transitions do not have a Soong equivalent.
 //
 // Mutate() does not make sense in Bazel due to the different models of the
 // two systems: when creating new variations, Soong clones the old module and
 // thus some way is needed to change it state whereas Bazel creates each
 // configuration of a given configured target anew.
 type TransitionMutator interface {
 	// Split returns the set of variations that should be created for a module no matter
 	// who depends on it. Used when Make depends on a particular variation or when
 	// the module knows its variations just based on information given to it in
 	// the Blueprint file. This method should not mutate the module it is called
 	// on.
 	Split(ctx BaseModuleContext) []string

 	// OutgoingTransition is called on a module to determine which variation it wants
 	// from its direct dependencies. The dependency itself can override this decision.
 	// This method should not mutate the module itself.
 	OutgoingTransition(ctx OutgoingTransitionContext, sourceVariation string) string

 	// IncomingTransition is called on a module to determine which variation it should
 	// be in based on the variation modules that depend on it want. This gives the module
 	// a final say about its own variations. This method should not mutate the module
 	// itself.
 	IncomingTransition(ctx IncomingTransitionContext, incomingVariation string) string

 	// Mutate is called after a module was split into multiple variations on each
 	// variation.  It should not split the module any further but adding new dependencies
 	// is fine. Unlike all the other methods on TransitionMutator, this method is
 	// allowed to mutate the module.
 	Mutate(ctx BottomUpMutatorContext, variation string)
 }

 type IncomingTransitionContext interface {
 	// Module returns the target of the dependency edge for which the transition
 	// is being computed
 	Module() Module

 	// Config returns the config object that was passed to
 	// Context.PrepareBuildActions.
 	Config() interface{}

 	// Provider returns the value for a provider for the target of the dependency edge for which the
 	// transition is being computed.  If the value is not set it returns nil and false.  It panics if
 	// called  before the appropriate mutator or GenerateBuildActions pass for the provider.  The value
 	// returned may be a deep copy of the value originally passed to SetProvider.
 	//
 	// This method shouldn't be used directly, prefer the type-safe android.ModuleProvider instead.
 	Provider(provider AnyProviderKey) (any, bool)
 }

 type OutgoingTransitionContext interface {
 	// Module returns the source of the dependency edge for which the transition
 	// is being computed
 	Module() Module

 	// DepTag() Returns the dependency tag through which this dependency is
 	// reached
 	DepTag() DependencyTag

 	// Config returns the config object that was passed to
 	// Context.PrepareBuildActions.
 	Config() interface{}

 	// Provider returns the value for a provider for the source of the dependency edge for which the
 	// transition is being computed.  If the value is not set it returns nil and false.  It panics if
 	// called before the appropriate mutator or GenerateBuildActions pass for the provider.  The value
 	// returned may be a deep copy of the value originally passed to SetProvider.
 	//
 	// This method shouldn't be used directly, prefer the type-safe android.ModuleProvider instead.
 	Provider(provider AnyProviderKey) (any, bool)
 }

 type transitionMutatorImpl struct {
 	name          string
 	mutator       TransitionMutator
 	inputVariants map[*moduleGroup][]*moduleInfo
 }

 // Adds each argument in items to l if it's not already there.
 func addToStringListIfNotPresent(l []string, items ...string) []string {
 	for _, i := range items {
 		if !slices.Contains(l, i) {
 			l = append(l, i)
 		}
 	}

 	return l
 }

 func (t *transitionMutatorImpl) addRequiredVariation(m *moduleInfo, variation string) {
 	m.requiredVariationsLock.Lock()
 	defer m.requiredVariationsLock.Unlock()

 	// This is only a consistency check. Leaking the variations of a transition
 	// mutator to another one could well lead to issues that are difficult to
 	// track down.
 	if m.currentTransitionMutator != "" && m.currentTransitionMutator != t.name {
 		panic(fmt.Errorf("transition mutator is %s in mutator %s", m.currentTransitionMutator, t.name))
 	}

 	m.currentTransitionMutator = t.name
 	m.transitionVariations = addToStringListIfNotPresent(m.transitionVariations, variation)
 }

 func (t *transitionMutatorImpl) topDownMutator(mctx TopDownMutatorContext) {
 	module := mctx.(*mutatorContext).module
 	mutatorSplits := t.mutator.Split(mctx)
 	if mutatorSplits == nil || len(mutatorSplits) == 0 {
 		panic(fmt.Errorf("transition mutator %s returned no splits for module %s", t.name, mctx.ModuleName()))
 	}

 	// transitionVariations for given a module can be mutated by the module itself
 	// and modules that directly depend on it. Since this is a top-down mutator,
 	// all modules that directly depend on this module have already been processed
 	// so no locking is necessary.
 	// Sort the module transitions, but keep the mutatorSplits in the order returned
 	// by Split, as the order can be significant when inter-variant dependencies are
 	// used.
 	sort.Strings(module.transitionVariations)
 	module.transitionVariations = addToStringListIfNotPresent(mutatorSplits, module.transitionVariations...)

 	outgoingTransitionCache := make([][]string, len(module.transitionVariations))
 	for srcVariationIndex, srcVariation := range module.transitionVariations {
 		srcVariationTransitionCache := make([]string, len(module.directDeps))
 		for depIndex, dep := range module.directDeps {
 			finalVariation := t.transition(mctx)(mctx.moduleInfo(), srcVariation, dep.module, dep.tag)
 			srcVariationTransitionCache[depIndex] = finalVariation
 			t.addRequiredVariation(dep.module, finalVariation)
 		}
 		outgoingTransitionCache[srcVariationIndex] = srcVariationTransitionCache
 	}
 	module.outgoingTransitionCache = outgoingTransitionCache
 }

 type transitionContextImpl struct {
 	context *Context
 	source  *moduleInfo
 	dep     *moduleInfo
 	depTag  DependencyTag
 	config  interface{}
 }

 func (c *transitionContextImpl) DepTag() DependencyTag {
 	return c.depTag
 }

 func (c *transitionContextImpl) Config() interface{} {
 	return c.config
 }

 type outgoingTransitionContextImpl struct {
 	transitionContextImpl
 }

 func (c *outgoingTransitionContextImpl) Module() Module {
 	return c.source.logicModule
 }

 func (c *outgoingTransitionContextImpl) Provider(provider AnyProviderKey) (any, bool) {
 	return c.context.provider(c.source, provider.provider())
 }

 type incomingTransitionContextImpl struct {
 	transitionContextImpl
 }

 func (c *incomingTransitionContextImpl) Module() Module {
 	return c.dep.logicModule
 }

 func (c *incomingTransitionContextImpl) Provider(provider AnyProviderKey) (any, bool) {
 	return c.context.provider(c.dep, provider.provider())
 }

 func (t *transitionMutatorImpl) transition(mctx BaseModuleContext) Transition {
 	return func(source *moduleInfo, sourceVariation string, dep *moduleInfo, depTag DependencyTag) string {
 		tc := transitionContextImpl{
 			context: mctx.base().context,
 			source:  source,
 			dep:     dep,
 			depTag:  depTag,
 			config:  mctx.Config(),
 		}
 		outgoingVariation := t.mutator.OutgoingTransition(&outgoingTransitionContextImpl{tc}, sourceVariation)
 		if mctx.Failed() {
 			return outgoingVariation
 		}
 		finalVariation := t.mutator.IncomingTransition(&incomingTransitionContextImpl{tc}, outgoingVariation)
 		return finalVariation
 	}
 }

 func (t *transitionMutatorImpl) bottomUpMutator(mctx BottomUpMutatorContext) {
 	mc := mctx.(*mutatorContext)
 	// Fetch and clean up transition mutator state. No locking needed since the
 	// only time interaction between multiple modules is required is during the
 	// computation of the variations required by a given module.
 	variations := mc.module.transitionVariations
 	outgoingTransitionCache := mc.module.outgoingTransitionCache
 	mc.module.transitionVariations = nil
 	mc.module.outgoingTransitionCache = nil
 	mc.module.currentTransitionMutator = ""

 	if len(variations) < 1 {
 		panic(fmt.Errorf("no variations found for module %s by mutator %s",
 			mctx.ModuleName(), t.name))
 	}

 	if len(variations) == 1 && variations[0] == "" {
 		// Module is not split, just apply the transition
 		mc.context.convertDepsToVariation(mc.module, 0,
 			chooseDepByIndexes(mc.mutator.name, outgoingTransitionCache))
 	} else {
 		mc.createVariationsWithTransition(variations, outgoingTransitionCache)
 	}
 }

 func (t *transitionMutatorImpl) mutateMutator(mctx BottomUpMutatorContext) {
 	module := mctx.(*mutatorContext).module
 	currentVariation := module.variant.variations[t.name]
 	t.mutator.Mutate(mctx, currentVariation)
 }

 func (c *Context) RegisterTransitionMutator(name string, mutator TransitionMutator) {
 	impl := &transitionMutatorImpl{name: name, mutator: mutator}

 	c.RegisterTopDownMutator(name+"_propagate", impl.topDownMutator).Parallel()
 	c.RegisterBottomUpMutator(name, impl.bottomUpMutator).Parallel().setTransitionMutator(impl)
 	c.RegisterBottomUpMutator(name+"_mutate", impl.mutateMutator).Parallel()
 }

 // This function is called for every dependency edge to determine which
 // variation of the dependency is needed. Its inputs are the depending module,
 // its variation, the dependency and the dependency tag.
 type Transition func(source *moduleInfo, sourceVariation string, dep *moduleInfo, depTag DependencyTag) string
	// Copyright 2024 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 blueprint

	import (
	"fmt"
	"slices"
	"sort"
	)

	// TransitionMutator implements a top-down mechanism where a module tells its
	// direct dependencies what variation they should be built in but the dependency
	// has the final say.
	//
	// When implementing a transition mutator, one needs to implement four methods:
	// - Split() that tells what variations a module has by itself
	// - OutgoingTransition() where a module tells what it wants from its
	// dependency
	// - IncomingTransition() where a module has the final say about its own
	// variation
	// - Mutate() that changes the state of a module depending on its variation
	//
	// That the effective variation of module B when depended on by module A is the
	// composition the outgoing transition of module A and the incoming transition
	// of module B.
	//
	// The outgoing transition should not take the properties of the dependency into
	// account, only those of the module that depends on it. For this reason, the
	// dependency is not even passed into it as an argument. Likewise, the incoming
	// transition should not take the properties of the depending module into
	// account and is thus not informed about it. This makes for a nice
	// decomposition of the decision logic.
	//
	// A given transition mutator only affects its own variation; other variations
	// stay unchanged along the dependency edges.
	//
	// Soong makes sure that all modules are created in the desired variations and
	// that dependency edges are set up correctly. This ensures that "missing
	// variation" errors do not happen and allows for more flexible changes in the
	// value of the variation among dependency edges (as opposed to bottom-up
	// mutators where if module A in variation X depends on module B and module B
	// has that variation X, A must depend on variation X of B)
	//
	// The limited power of the context objects passed to individual mutators
	// methods also makes it more difficult to shoot oneself in the foot. Complete
	// safety is not guaranteed because no one prevents individual transition
	// mutators from mutating modules in illegal ways and for e.g. Split() or
	// Mutate() to run their own visitations of the transitive dependency of the
	// module and both of these are bad ideas, but it's better than no guardrails at
	// all.
	//
	// This model is pretty close to Bazel's configuration transitions. The mapping
	// between concepts in Soong and Bazel is as follows:
	// - Module == configured target
	// - Variant == configuration
	// - Variation name == configuration flag
	// - Variation == configuration flag value
	// - Outgoing transition == attribute transition
	// - Incoming transition == rule transition
	//
	// The Split() method does not have a Bazel equivalent and Bazel split
	// transitions do not have a Soong equivalent.
	//
	// Mutate() does not make sense in Bazel due to the different models of the
	// two systems: when creating new variations, Soong clones the old module and
	// thus some way is needed to change it state whereas Bazel creates each
	// configuration of a given configured target anew.
	type TransitionMutator interface {
	// Split returns the set of variations that should be created for a module no matter
	// who depends on it. Used when Make depends on a particular variation or when
	// the module knows its variations just based on information given to it in
	// the Blueprint file. This method should not mutate the module it is called
	// on.
	Split(ctx BaseModuleContext) []string

	// OutgoingTransition is called on a module to determine which variation it wants
	// from its direct dependencies. The dependency itself can override this decision.
	// This method should not mutate the module itself.
	OutgoingTransition(ctx OutgoingTransitionContext, sourceVariation string) string

	// IncomingTransition is called on a module to determine which variation it should
	// be in based on the variation modules that depend on it want. This gives the module
	// a final say about its own variations. This method should not mutate the module
	// itself.
	IncomingTransition(ctx IncomingTransitionContext, incomingVariation string) string

	// Mutate is called after a module was split into multiple variations on each
	// variation. It should not split the module any further but adding new dependencies
	// is fine. Unlike all the other methods on TransitionMutator, this method is
	// allowed to mutate the module.
	Mutate(ctx BottomUpMutatorContext, variation string)
	}

	type IncomingTransitionContext interface {
	// Module returns the target of the dependency edge for which the transition
	// is being computed
	Module() Module

	// Config returns the config object that was passed to
	// Context.PrepareBuildActions.
	Config() interface{}

	// Provider returns the value for a provider for the target of the dependency edge for which the
	// transition is being computed. If the value is not set it returns nil and false. It panics if
	// called before the appropriate mutator or GenerateBuildActions pass for the provider. The value
	// returned may be a deep copy of the value originally passed to SetProvider.
	//
	// This method shouldn't be used directly, prefer the type-safe android.ModuleProvider instead.
	Provider(provider AnyProviderKey) (any, bool)
	}

	type OutgoingTransitionContext interface {
	// Module returns the source of the dependency edge for which the transition
	// is being computed
	Module() Module

	// DepTag() Returns the dependency tag through which this dependency is
	// reached
	DepTag() DependencyTag

	// Config returns the config object that was passed to
	// Context.PrepareBuildActions.
	Config() interface{}

	// Provider returns the value for a provider for the source of the dependency edge for which the
	// transition is being computed. If the value is not set it returns nil and false. It panics if
	// called before the appropriate mutator or GenerateBuildActions pass for the provider. The value
	// returned may be a deep copy of the value originally passed to SetProvider.
	//
	// This method shouldn't be used directly, prefer the type-safe android.ModuleProvider instead.
	Provider(provider AnyProviderKey) (any, bool)
	}

	type transitionMutatorImpl struct {
	name string
	mutator TransitionMutator
	inputVariants map[moduleGroup][]moduleInfo
	}

	// Adds each argument in items to l if it's not already there.
	func addToStringListIfNotPresent(l []string, items ...string) []string {
	for _, i := range items {
	if !slices.Contains(l, i) {
	l = append(l, i)
	}
	}

	return l
	}

	func (t transitionMutatorImpl) addRequiredVariation(m moduleInfo, variation string) {
	m.requiredVariationsLock.Lock()
	defer m.requiredVariationsLock.Unlock()

	// This is only a consistency check. Leaking the variations of a transition
	// mutator to another one could well lead to issues that are difficult to
	// track down.
	if m.currentTransitionMutator != "" && m.currentTransitionMutator != t.name {
	panic(fmt.Errorf("transition mutator is %s in mutator %s", m.currentTransitionMutator, t.name))
	}

	m.currentTransitionMutator = t.name
	m.transitionVariations = addToStringListIfNotPresent(m.transitionVariations, variation)
	}

	func (t *transitionMutatorImpl) topDownMutator(mctx TopDownMutatorContext) {
	module := mctx.(*mutatorContext).module
	mutatorSplits := t.mutator.Split(mctx)
	if mutatorSplits == nil \|\| len(mutatorSplits) == 0 {
	panic(fmt.Errorf("transition mutator %s returned no splits for module %s", t.name, mctx.ModuleName()))
	}

	// transitionVariations for given a module can be mutated by the module itself
	// and modules that directly depend on it. Since this is a top-down mutator,
	// all modules that directly depend on this module have already been processed
	// so no locking is necessary.
	// Sort the module transitions, but keep the mutatorSplits in the order returned
	// by Split, as the order can be significant when inter-variant dependencies are
	// used.
	sort.Strings(module.transitionVariations)
	module.transitionVariations = addToStringListIfNotPresent(mutatorSplits, module.transitionVariations...)

	outgoingTransitionCache := make([][]string, len(module.transitionVariations))
	for srcVariationIndex, srcVariation := range module.transitionVariations {
	srcVariationTransitionCache := make([]string, len(module.directDeps))
	for depIndex, dep := range module.directDeps {
	finalVariation := t.transition(mctx)(mctx.moduleInfo(), srcVariation, dep.module, dep.tag)
	srcVariationTransitionCache[depIndex] = finalVariation
	t.addRequiredVariation(dep.module, finalVariation)
	}
	outgoingTransitionCache[srcVariationIndex] = srcVariationTransitionCache
	}
	module.outgoingTransitionCache = outgoingTransitionCache
	}

	type transitionContextImpl struct {
	context *Context
	source *moduleInfo
	dep *moduleInfo
	depTag DependencyTag
	config interface{}
	}

	func (c *transitionContextImpl) DepTag() DependencyTag {
	return c.depTag
	}

	func (c *transitionContextImpl) Config() interface{} {
	return c.config
	}

	type outgoingTransitionContextImpl struct {
	transitionContextImpl
	}

	func (c *outgoingTransitionContextImpl) Module() Module {
	return c.source.logicModule
	}

	func (c *outgoingTransitionContextImpl) Provider(provider AnyProviderKey) (any, bool) {
	return c.context.provider(c.source, provider.provider())
	}

	type incomingTransitionContextImpl struct {
	transitionContextImpl
	}

	func (c *incomingTransitionContextImpl) Module() Module {
	return c.dep.logicModule
	}

	func (c *incomingTransitionContextImpl) Provider(provider AnyProviderKey) (any, bool) {
	return c.context.provider(c.dep, provider.provider())
	}

	func (t *transitionMutatorImpl) transition(mctx BaseModuleContext) Transition {
	return func(source moduleInfo, sourceVariation string, dep moduleInfo, depTag DependencyTag) string {
	tc := transitionContextImpl{
	context: mctx.base().context,
	source: source,
	dep: dep,
	depTag: depTag,
	config: mctx.Config(),
	}
	outgoingVariation := t.mutator.OutgoingTransition(&outgoingTransitionContextImpl{tc}, sourceVariation)
	if mctx.Failed() {
	return outgoingVariation
	}
	finalVariation := t.mutator.IncomingTransition(&incomingTransitionContextImpl{tc}, outgoingVariation)
	return finalVariation
	}
	}

	func (t *transitionMutatorImpl) bottomUpMutator(mctx BottomUpMutatorContext) {
	mc := mctx.(*mutatorContext)
	// Fetch and clean up transition mutator state. No locking needed since the
	// only time interaction between multiple modules is required is during the
	// computation of the variations required by a given module.
	variations := mc.module.transitionVariations
	outgoingTransitionCache := mc.module.outgoingTransitionCache
	mc.module.transitionVariations = nil
	mc.module.outgoingTransitionCache = nil
	mc.module.currentTransitionMutator = ""

	if len(variations) < 1 {
	panic(fmt.Errorf("no variations found for module %s by mutator %s",
	mctx.ModuleName(), t.name))
	}

	if len(variations) == 1 && variations[0] == "" {
	// Module is not split, just apply the transition
	mc.context.convertDepsToVariation(mc.module, 0,
	chooseDepByIndexes(mc.mutator.name, outgoingTransitionCache))
	} else {
	mc.createVariationsWithTransition(variations, outgoingTransitionCache)
	}
	}

	func (t *transitionMutatorImpl) mutateMutator(mctx BottomUpMutatorContext) {
	module := mctx.(*mutatorContext).module
	currentVariation := module.variant.variations[t.name]
	t.mutator.Mutate(mctx, currentVariation)
	}

	func (c *Context) RegisterTransitionMutator(name string, mutator TransitionMutator) {
	impl := &transitionMutatorImpl{name: name, mutator: mutator}

	c.RegisterTopDownMutator(name+"_propagate", impl.topDownMutator).Parallel()
	c.RegisterBottomUpMutator(name, impl.bottomUpMutator).Parallel().setTransitionMutator(impl)
	c.RegisterBottomUpMutator(name+"_mutate", impl.mutateMutator).Parallel()
	}

	// This function is called for every dependency edge to determine which
	// variation of the dependency is needed. Its inputs are the depending module,
	// its variation, the dependency and the dependency tag.
	type Transition func(source moduleInfo, sourceVariation string, dep moduleInfo, depTag DependencyTag) string