352 lines
12 KiB
Go
352 lines
12 KiB
Go
// Copyright 2020 Google Inc. All rights reserved.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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package android
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import (
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"fmt"
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"reflect"
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)
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// depSet is designed to be conceptually compatible with Bazel's depsets:
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// https://docs.bazel.build/versions/master/skylark/depsets.html
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type DepSetOrder int
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const (
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PREORDER DepSetOrder = iota
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POSTORDER
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TOPOLOGICAL
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)
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func (o DepSetOrder) String() string {
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switch o {
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case PREORDER:
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return "PREORDER"
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case POSTORDER:
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return "POSTORDER"
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case TOPOLOGICAL:
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return "TOPOLOGICAL"
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default:
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panic(fmt.Errorf("Invalid DepSetOrder %d", o))
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}
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}
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// A depSet efficiently stores a slice of an arbitrary type from transitive dependencies without
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// copying. It is stored as a DAG of depSet nodes, each of which has some direct contents and a list
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// of dependency depSet nodes.
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//
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// A depSet has an order that will be used to walk the DAG when ToList() is called. The order
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// can be POSTORDER, PREORDER, or TOPOLOGICAL. POSTORDER and PREORDER orders return a postordered
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// or preordered left to right flattened list. TOPOLOGICAL returns a list that guarantees that
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// elements of children are listed after all of their parents (unless there are duplicate direct
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// elements in the depSet or any of its transitive dependencies, in which case the ordering of the
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// duplicated element is not guaranteed).
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//
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// A depSet is created by newDepSet or newDepSetBuilder.Build from the slice for direct contents
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// and the *depSets of dependencies. A depSet is immutable once created.
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//
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// This object uses reflection to remain agnostic to the type it contains. It should be replaced
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// with generics once those exist in Go. Callers should generally use a thin wrapper around depSet
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// that provides type-safe methods like DepSet for Paths.
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type depSet struct {
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preorder bool
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reverse bool
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order DepSetOrder
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direct interface{}
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transitive []*depSet
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}
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type depSetInterface interface {
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embeddedDepSet() *depSet
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}
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func (d *depSet) embeddedDepSet() *depSet {
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return d
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}
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var _ depSetInterface = (*depSet)(nil)
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// newDepSet returns an immutable depSet with the given order, direct and transitive contents.
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// direct must be a slice, but is not type-safe due to the lack of generics in Go. It can be a
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// nil slice, but not a nil interface{}, i.e. []string(nil) but not nil.
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func newDepSet(order DepSetOrder, direct interface{}, transitive interface{}) *depSet {
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var directCopy interface{}
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transitiveDepSet := sliceToDepSets(transitive, order)
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if order == TOPOLOGICAL {
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directCopy = reverseSlice(direct)
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reverseSliceInPlace(transitiveDepSet)
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} else {
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directCopy = copySlice(direct)
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}
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return &depSet{
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preorder: order == PREORDER,
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reverse: order == TOPOLOGICAL,
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order: order,
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direct: directCopy,
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transitive: transitiveDepSet,
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}
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}
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// depSetBuilder is used to create an immutable depSet.
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type depSetBuilder struct {
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order DepSetOrder
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direct reflect.Value
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transitive []*depSet
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}
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// newDepSetBuilder returns a depSetBuilder to create an immutable depSet with the given order and
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// type, represented by a slice of type that will be in the depSet.
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func newDepSetBuilder(order DepSetOrder, typ interface{}) *depSetBuilder {
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empty := reflect.Zero(reflect.TypeOf(typ))
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return &depSetBuilder{
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order: order,
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direct: empty,
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}
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}
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// sliceToDepSets converts a slice of any type that implements depSetInterface (by having a depSet
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// embedded in it) into a []*depSet.
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func sliceToDepSets(in interface{}, order DepSetOrder) []*depSet {
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slice := reflect.ValueOf(in)
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length := slice.Len()
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out := make([]*depSet, length)
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for i := 0; i < length; i++ {
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vi := slice.Index(i)
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depSetIntf, ok := vi.Interface().(depSetInterface)
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if !ok {
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panic(fmt.Errorf("element %d is a %s, not a depSetInterface", i, vi.Type()))
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}
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depSet := depSetIntf.embeddedDepSet()
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if depSet.order != order {
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panic(fmt.Errorf("incompatible order, new depSet is %s but transitive depSet is %s",
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order, depSet.order))
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}
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out[i] = depSet
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}
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return out
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}
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// DirectSlice adds direct contents to the depSet being built by a depSetBuilder. Newly added direct
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// contents are to the right of any existing direct contents. The argument must be a slice, but
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// is not type-safe due to the lack of generics in Go.
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func (b *depSetBuilder) DirectSlice(direct interface{}) *depSetBuilder {
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b.direct = reflect.AppendSlice(b.direct, reflect.ValueOf(direct))
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return b
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}
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// Direct adds direct contents to the depSet being built by a depSetBuilder. Newly added direct
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// contents are to the right of any existing direct contents. The argument must be the same type
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// as the element of the slice passed to newDepSetBuilder, but is not type-safe due to the lack of
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// generics in Go.
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func (b *depSetBuilder) Direct(direct interface{}) *depSetBuilder {
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b.direct = reflect.Append(b.direct, reflect.ValueOf(direct))
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return b
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}
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// Transitive adds transitive contents to the DepSet being built by a DepSetBuilder. Newly added
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// transitive contents are to the right of any existing transitive contents. The argument can
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// be any slice of type that has depSet embedded in it.
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func (b *depSetBuilder) Transitive(transitive interface{}) *depSetBuilder {
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depSets := sliceToDepSets(transitive, b.order)
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b.transitive = append(b.transitive, depSets...)
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return b
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}
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// Returns the depSet being built by this depSetBuilder. The depSetBuilder retains its contents
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// for creating more depSets.
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func (b *depSetBuilder) Build() *depSet {
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return newDepSet(b.order, b.direct.Interface(), b.transitive)
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}
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// walk calls the visit method in depth-first order on a DepSet, preordered if d.preorder is set,
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// otherwise postordered.
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func (d *depSet) walk(visit func(interface{})) {
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visited := make(map[*depSet]bool)
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var dfs func(d *depSet)
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dfs = func(d *depSet) {
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visited[d] = true
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if d.preorder {
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visit(d.direct)
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}
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for _, dep := range d.transitive {
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if !visited[dep] {
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dfs(dep)
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}
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}
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if !d.preorder {
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visit(d.direct)
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}
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}
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dfs(d)
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}
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// ToList returns the depSet flattened to a list. The order in the list is based on the order
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// of the depSet. POSTORDER and PREORDER orders return a postordered or preordered left to right
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// flattened list. TOPOLOGICAL returns a list that guarantees that elements of children are listed
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// after all of their parents (unless there are duplicate direct elements in the DepSet or any of
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// its transitive dependencies, in which case the ordering of the duplicated element is not
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// guaranteed).
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//
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// This method uses a reflection-based implementation to find the unique elements in slice, which
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// is around 3x slower than a concrete implementation. Type-safe wrappers around depSet can
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// provide their own implementation of ToList that calls depSet.toList with a method that
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// uses a concrete implementation.
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func (d *depSet) ToList() interface{} {
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return d.toList(firstUnique)
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}
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// toList returns the depSet flattened to a list. The order in the list is based on the order
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// of the depSet. POSTORDER and PREORDER orders return a postordered or preordered left to right
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// flattened list. TOPOLOGICAL returns a list that guarantees that elements of children are listed
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// after all of their parents (unless there are duplicate direct elements in the DepSet or any of
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// its transitive dependencies, in which case the ordering of the duplicated element is not
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// guaranteed). The firstUniqueFunc is used to remove duplicates from the list.
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func (d *depSet) toList(firstUniqueFunc func(interface{}) interface{}) interface{} {
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if d == nil {
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return nil
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}
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slice := reflect.Zero(reflect.TypeOf(d.direct))
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d.walk(func(paths interface{}) {
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slice = reflect.AppendSlice(slice, reflect.ValueOf(paths))
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})
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list := slice.Interface()
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list = firstUniqueFunc(list)
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if d.reverse {
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reverseSliceInPlace(list)
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}
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return list
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}
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// firstUnique returns all unique elements of a slice, keeping the first copy of each. It
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// modifies the slice contents in place, and returns a subslice of the original slice. The
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// argument must be a slice, but is not type-safe due to the lack of reflection in Go.
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//
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// Performance of the reflection-based firstUnique is up to 3x slower than a concrete type
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// version such as FirstUniqueStrings.
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func firstUnique(slice interface{}) interface{} {
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// 4 was chosen based on Benchmark_firstUnique results.
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if reflect.ValueOf(slice).Len() > 4 {
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return firstUniqueMap(slice)
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}
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return firstUniqueList(slice)
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}
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// firstUniqueList is an implementation of firstUnique using an O(N^2) list comparison to look for
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// duplicates.
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func firstUniqueList(in interface{}) interface{} {
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writeIndex := 0
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slice := reflect.ValueOf(in)
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length := slice.Len()
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outer:
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for readIndex := 0; readIndex < length; readIndex++ {
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readValue := slice.Index(readIndex)
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for compareIndex := 0; compareIndex < writeIndex; compareIndex++ {
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compareValue := slice.Index(compareIndex)
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// These two Interface() calls seem to cause an allocation and significantly
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// slow down this list-based implementation. The map implementation below doesn't
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// have this issue because reflect.Value.MapIndex takes a Value and appears to be
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// able to do the map lookup without an allocation.
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if readValue.Interface() == compareValue.Interface() {
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// The value at readIndex already exists somewhere in the output region
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// of the slice before writeIndex, skip it.
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continue outer
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}
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}
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if readIndex != writeIndex {
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writeValue := slice.Index(writeIndex)
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writeValue.Set(readValue)
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}
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writeIndex++
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}
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return slice.Slice(0, writeIndex).Interface()
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}
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var trueValue = reflect.ValueOf(true)
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// firstUniqueList is an implementation of firstUnique using an O(N) hash set lookup to look for
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// duplicates.
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func firstUniqueMap(in interface{}) interface{} {
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writeIndex := 0
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slice := reflect.ValueOf(in)
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length := slice.Len()
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seen := reflect.MakeMapWithSize(reflect.MapOf(slice.Type().Elem(), trueValue.Type()), slice.Len())
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for readIndex := 0; readIndex < length; readIndex++ {
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readValue := slice.Index(readIndex)
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if seen.MapIndex(readValue).IsValid() {
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continue
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}
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seen.SetMapIndex(readValue, trueValue)
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if readIndex != writeIndex {
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writeValue := slice.Index(writeIndex)
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writeValue.Set(readValue)
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}
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writeIndex++
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}
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return slice.Slice(0, writeIndex).Interface()
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}
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// reverseSliceInPlace reverses the elements of a slice in place. The argument must be a slice, but
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// is not type-safe due to the lack of reflection in Go.
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func reverseSliceInPlace(in interface{}) {
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swapper := reflect.Swapper(in)
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slice := reflect.ValueOf(in)
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length := slice.Len()
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for i, j := 0, length-1; i < j; i, j = i+1, j-1 {
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swapper(i, j)
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}
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}
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// reverseSlice returns a copy of a slice in reverse order. The argument must be a slice, but is
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// not type-safe due to the lack of reflection in Go.
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func reverseSlice(in interface{}) interface{} {
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slice := reflect.ValueOf(in)
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if !slice.IsValid() || slice.IsNil() {
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return in
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}
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if slice.Kind() != reflect.Slice {
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panic(fmt.Errorf("%t is not a slice", in))
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}
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length := slice.Len()
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if length == 0 {
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return in
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}
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out := reflect.MakeSlice(slice.Type(), length, length)
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for i := 0; i < length; i++ {
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out.Index(i).Set(slice.Index(length - 1 - i))
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}
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return out.Interface()
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}
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// copySlice returns a copy of a slice. The argument must be a slice, but is not type-safe due to
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// the lack of reflection in Go.
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func copySlice(in interface{}) interface{} {
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slice := reflect.ValueOf(in)
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if !slice.IsValid() || slice.IsNil() {
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return in
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}
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length := slice.Len()
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if length == 0 {
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return in
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}
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out := reflect.MakeSlice(slice.Type(), length, length)
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reflect.Copy(out, slice)
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return out.Interface()
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}
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