platform_build_soong/android/depset_generic.go
Wen-yi Chu 41326c1f41 Revert "support sandboxed rust rules"
Revert submission 2629131-sandbox-rust-inputs

Reason for revert: Fail on android build.

Reverted changes: /q/submissionid:2629131-sandbox-rust-inputs

Change-Id: Ifd9aa46e80a12d8f4ffa0a2daa74b96727cbb7e6
2023-09-22 22:05:54 +00:00

190 lines
6 KiB
Go

// Copyright 2020 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"
)
// DepSet is designed to be conceptually compatible with Bazel's depsets:
// https://docs.bazel.build/versions/master/skylark/depsets.html
type DepSetOrder int
const (
PREORDER DepSetOrder = iota
POSTORDER
TOPOLOGICAL
)
func (o DepSetOrder) String() string {
switch o {
case PREORDER:
return "PREORDER"
case POSTORDER:
return "POSTORDER"
case TOPOLOGICAL:
return "TOPOLOGICAL"
default:
panic(fmt.Errorf("Invalid DepSetOrder %d", o))
}
}
type depSettableType comparable
// A DepSet efficiently stores a slice of an arbitrary type from transitive dependencies without
// copying. It is stored as a DAG of DepSet nodes, each of which has some direct contents and a list
// of dependency DepSet nodes.
//
// A DepSet has an order that will be used to walk the DAG when ToList() is called. The order
// can be POSTORDER, PREORDER, or TOPOLOGICAL. POSTORDER and PREORDER orders return a postordered
// or preordered left to right flattened list. TOPOLOGICAL returns a list that guarantees that
// elements of children are listed after all of their parents (unless there are duplicate direct
// elements in the DepSet or any of its transitive dependencies, in which case the ordering of the
// duplicated element is not guaranteed).
//
// A DepSet is created by NewDepSet or NewDepSetBuilder.Build from the slice for direct contents
// and the *DepSets of dependencies. A DepSet is immutable once created.
type DepSet[T depSettableType] struct {
preorder bool
reverse bool
order DepSetOrder
direct []T
transitive []*DepSet[T]
}
// NewDepSet returns an immutable DepSet with the given order, direct and transitive contents.
func NewDepSet[T depSettableType](order DepSetOrder, direct []T, transitive []*DepSet[T]) *DepSet[T] {
var directCopy []T
var transitiveCopy []*DepSet[T]
for _, t := range transitive {
if t.order != order {
panic(fmt.Errorf("incompatible order, new DepSet is %s but transitive DepSet is %s",
order, t.order))
}
}
if order == TOPOLOGICAL {
// TOPOLOGICAL is implemented as a postorder traversal followed by reversing the output.
// Pre-reverse the inputs here so their order is maintained in the output.
directCopy = ReverseSlice(direct)
transitiveCopy = ReverseSlice(transitive)
} else {
directCopy = append([]T(nil), direct...)
transitiveCopy = append([]*DepSet[T](nil), transitive...)
}
return &DepSet[T]{
preorder: order == PREORDER,
reverse: order == TOPOLOGICAL,
order: order,
direct: directCopy,
transitive: transitiveCopy,
}
}
// DepSetBuilder is used to create an immutable DepSet.
type DepSetBuilder[T depSettableType] struct {
order DepSetOrder
direct []T
transitive []*DepSet[T]
}
// NewDepSetBuilder returns a DepSetBuilder to create an immutable DepSet with the given order and
// type, represented by a slice of type that will be in the DepSet.
func NewDepSetBuilder[T depSettableType](order DepSetOrder) *DepSetBuilder[T] {
return &DepSetBuilder[T]{
order: order,
}
}
// DirectSlice adds direct contents to the DepSet being built by a DepSetBuilder. Newly added direct
// contents are to the right of any existing direct contents.
func (b *DepSetBuilder[T]) DirectSlice(direct []T) *DepSetBuilder[T] {
b.direct = append(b.direct, direct...)
return b
}
// Direct adds direct contents to the DepSet being built by a DepSetBuilder. Newly added direct
// contents are to the right of any existing direct contents.
func (b *DepSetBuilder[T]) Direct(direct ...T) *DepSetBuilder[T] {
b.direct = append(b.direct, direct...)
return b
}
// Transitive adds transitive contents to the DepSet being built by a DepSetBuilder. Newly added
// transitive contents are to the right of any existing transitive contents.
func (b *DepSetBuilder[T]) Transitive(transitive ...*DepSet[T]) *DepSetBuilder[T] {
for _, t := range transitive {
if t.order != b.order {
panic(fmt.Errorf("incompatible order, new DepSet is %s but transitive DepSet is %s",
b.order, t.order))
}
}
b.transitive = append(b.transitive, transitive...)
return b
}
// Returns the DepSet being built by this DepSetBuilder. The DepSetBuilder retains its contents
// for creating more depSets.
func (b *DepSetBuilder[T]) Build() *DepSet[T] {
return NewDepSet(b.order, b.direct, b.transitive)
}
// walk calls the visit method in depth-first order on a DepSet, preordered if d.preorder is set,
// otherwise postordered.
func (d *DepSet[T]) walk(visit func([]T)) {
visited := make(map[*DepSet[T]]bool)
var dfs func(d *DepSet[T])
dfs = func(d *DepSet[T]) {
visited[d] = true
if d.preorder {
visit(d.direct)
}
for _, dep := range d.transitive {
if !visited[dep] {
dfs(dep)
}
}
if !d.preorder {
visit(d.direct)
}
}
dfs(d)
}
// ToList returns the DepSet flattened to a list. The order in the list is based on the order
// of the DepSet. POSTORDER and PREORDER orders return a postordered or preordered left to right
// flattened list. TOPOLOGICAL returns a list that guarantees that elements of children are listed
// after all of their parents (unless there are duplicate direct elements in the DepSet or any of
// its transitive dependencies, in which case the ordering of the duplicated element is not
// guaranteed).
func (d *DepSet[T]) ToList() []T {
if d == nil {
return nil
}
var list []T
d.walk(func(paths []T) {
list = append(list, paths...)
})
list = firstUniqueInPlace(list)
if d.reverse {
ReverseSliceInPlace(list)
}
return list
}