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go/godoc/vfs/namespace.go
Agniva De Sarker 8b3cccae50 godoc/vfs: improve implementation of RootType
- Removed the StandAlone and Asset root types as they were just there
for other vfses to satisfy the FileSystem interface and causing unnecessary
confusion. Returning just empty strings in those scenarios now to clarify
that it is a dummy placeholder.

- Removed the prefix "Fs" from RootType as it was unnecessary.

- Using the RootType type to pass down to the html templates
instead of converting to string. The templates are capable of converting
to the actual string representation when comparing the value.

Change-Id: Iadc039f1354ecd814eec0af1e52cdbaaeff0cc89
Reviewed-on: https://go-review.googlesource.com/106196
Reviewed-by: Brad Fitzpatrick <bradfitz@golang.org>
2018-04-11 20:41:25 +00:00

404 lines
12 KiB
Go

// Copyright 2011 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package vfs
import (
"fmt"
"io"
"os"
pathpkg "path"
"sort"
"strings"
"time"
)
// Setting debugNS = true will enable debugging prints about
// name space translations.
const debugNS = false
// A NameSpace is a file system made up of other file systems
// mounted at specific locations in the name space.
//
// The representation is a map from mount point locations
// to the list of file systems mounted at that location. A traditional
// Unix mount table would use a single file system per mount point,
// but we want to be able to mount multiple file systems on a single
// mount point and have the system behave as if the union of those
// file systems were present at the mount point.
// For example, if the OS file system has a Go installation in
// c:\Go and additional Go path trees in d:\Work1 and d:\Work2, then
// this name space creates the view we want for the godoc server:
//
// NameSpace{
// "/": {
// {old: "/", fs: OS(`c:\Go`), new: "/"},
// },
// "/src/pkg": {
// {old: "/src/pkg", fs: OS(`c:\Go`), new: "/src/pkg"},
// {old: "/src/pkg", fs: OS(`d:\Work1`), new: "/src"},
// {old: "/src/pkg", fs: OS(`d:\Work2`), new: "/src"},
// },
// }
//
// This is created by executing:
//
// ns := NameSpace{}
// ns.Bind("/", OS(`c:\Go`), "/", BindReplace)
// ns.Bind("/src/pkg", OS(`d:\Work1`), "/src", BindAfter)
// ns.Bind("/src/pkg", OS(`d:\Work2`), "/src", BindAfter)
//
// A particular mount point entry is a triple (old, fs, new), meaning that to
// operate on a path beginning with old, replace that prefix (old) with new
// and then pass that path to the FileSystem implementation fs.
//
// If you do not explicitly mount a FileSystem at the root mountpoint "/" of the
// NameSpace like above, Stat("/") will return a "not found" error which could
// break typical directory traversal routines. In such cases, use NewNameSpace()
// to get a NameSpace pre-initialized with an emulated empty directory at root.
//
// Given this name space, a ReadDir of /src/pkg/code will check each prefix
// of the path for a mount point (first /src/pkg/code, then /src/pkg, then /src,
// then /), stopping when it finds one. For the above example, /src/pkg/code
// will find the mount point at /src/pkg:
//
// {old: "/src/pkg", fs: OS(`c:\Go`), new: "/src/pkg"},
// {old: "/src/pkg", fs: OS(`d:\Work1`), new: "/src"},
// {old: "/src/pkg", fs: OS(`d:\Work2`), new: "/src"},
//
// ReadDir will when execute these three calls and merge the results:
//
// OS(`c:\Go`).ReadDir("/src/pkg/code")
// OS(`d:\Work1').ReadDir("/src/code")
// OS(`d:\Work2').ReadDir("/src/code")
//
// Note that the "/src/pkg" in "/src/pkg/code" has been replaced by
// just "/src" in the final two calls.
//
// OS is itself an implementation of a file system: it implements
// OS(`c:\Go`).ReadDir("/src/pkg/code") as ioutil.ReadDir(`c:\Go\src\pkg\code`).
//
// Because the new path is evaluated by fs (here OS(root)), another way
// to read the mount table is to mentally combine fs+new, so that this table:
//
// {old: "/src/pkg", fs: OS(`c:\Go`), new: "/src/pkg"},
// {old: "/src/pkg", fs: OS(`d:\Work1`), new: "/src"},
// {old: "/src/pkg", fs: OS(`d:\Work2`), new: "/src"},
//
// reads as:
//
// "/src/pkg" -> c:\Go\src\pkg
// "/src/pkg" -> d:\Work1\src
// "/src/pkg" -> d:\Work2\src
//
// An invariant (a redundancy) of the name space representation is that
// ns[mtpt][i].old is always equal to mtpt (in the example, ns["/src/pkg"]'s
// mount table entries always have old == "/src/pkg"). The 'old' field is
// useful to callers, because they receive just a []mountedFS and not any
// other indication of which mount point was found.
//
type NameSpace map[string][]mountedFS
// A mountedFS handles requests for path by replacing
// a prefix 'old' with 'new' and then calling the fs methods.
type mountedFS struct {
old string
fs FileSystem
new string
}
// hasPathPrefix returns true if x == y or x == y + "/" + more
func hasPathPrefix(x, y string) bool {
return x == y || strings.HasPrefix(x, y) && (strings.HasSuffix(y, "/") || strings.HasPrefix(x[len(y):], "/"))
}
// translate translates path for use in m, replacing old with new.
//
// mountedFS{"/src/pkg", fs, "/src"}.translate("/src/pkg/code") == "/src/code".
func (m mountedFS) translate(path string) string {
path = pathpkg.Clean("/" + path)
if !hasPathPrefix(path, m.old) {
panic("translate " + path + " but old=" + m.old)
}
return pathpkg.Join(m.new, path[len(m.old):])
}
func (NameSpace) String() string {
return "ns"
}
// Fprint writes a text representation of the name space to w.
func (ns NameSpace) Fprint(w io.Writer) {
fmt.Fprint(w, "name space {\n")
var all []string
for mtpt := range ns {
all = append(all, mtpt)
}
sort.Strings(all)
for _, mtpt := range all {
fmt.Fprintf(w, "\t%s:\n", mtpt)
for _, m := range ns[mtpt] {
fmt.Fprintf(w, "\t\t%s %s\n", m.fs, m.new)
}
}
fmt.Fprint(w, "}\n")
}
// clean returns a cleaned, rooted path for evaluation.
// It canonicalizes the path so that we can use string operations
// to analyze it.
func (NameSpace) clean(path string) string {
return pathpkg.Clean("/" + path)
}
type BindMode int
const (
BindReplace BindMode = iota
BindBefore
BindAfter
)
// Bind causes references to old to redirect to the path new in newfs.
// If mode is BindReplace, old redirections are discarded.
// If mode is BindBefore, this redirection takes priority over existing ones,
// but earlier ones are still consulted for paths that do not exist in newfs.
// If mode is BindAfter, this redirection happens only after existing ones
// have been tried and failed.
func (ns NameSpace) Bind(old string, newfs FileSystem, new string, mode BindMode) {
old = ns.clean(old)
new = ns.clean(new)
m := mountedFS{old, newfs, new}
var mtpt []mountedFS
switch mode {
case BindReplace:
mtpt = append(mtpt, m)
case BindAfter:
mtpt = append(mtpt, ns.resolve(old)...)
mtpt = append(mtpt, m)
case BindBefore:
mtpt = append(mtpt, m)
mtpt = append(mtpt, ns.resolve(old)...)
}
// Extend m.old, m.new in inherited mount point entries.
for i := range mtpt {
m := &mtpt[i]
if m.old != old {
if !hasPathPrefix(old, m.old) {
// This should not happen. If it does, panic so
// that we can see the call trace that led to it.
panic(fmt.Sprintf("invalid Bind: old=%q m={%q, %s, %q}", old, m.old, m.fs.String(), m.new))
}
suffix := old[len(m.old):]
m.old = pathpkg.Join(m.old, suffix)
m.new = pathpkg.Join(m.new, suffix)
}
}
ns[old] = mtpt
}
// resolve resolves a path to the list of mountedFS to use for path.
func (ns NameSpace) resolve(path string) []mountedFS {
path = ns.clean(path)
for {
if m := ns[path]; m != nil {
if debugNS {
fmt.Printf("resolve %s: %v\n", path, m)
}
return m
}
if path == "/" {
break
}
path = pathpkg.Dir(path)
}
return nil
}
// Open implements the FileSystem Open method.
func (ns NameSpace) Open(path string) (ReadSeekCloser, error) {
var err error
for _, m := range ns.resolve(path) {
if debugNS {
fmt.Printf("tx %s: %v\n", path, m.translate(path))
}
tp := m.translate(path)
r, err1 := m.fs.Open(tp)
if err1 == nil {
return r, nil
}
// IsNotExist errors in overlay FSes can mask real errors in
// the underlying FS, so ignore them if there is another error.
if err == nil || os.IsNotExist(err) {
err = err1
}
}
if err == nil {
err = &os.PathError{Op: "open", Path: path, Err: os.ErrNotExist}
}
return nil, err
}
// stat implements the FileSystem Stat and Lstat methods.
func (ns NameSpace) stat(path string, f func(FileSystem, string) (os.FileInfo, error)) (os.FileInfo, error) {
var err error
for _, m := range ns.resolve(path) {
fi, err1 := f(m.fs, m.translate(path))
if err1 == nil {
return fi, nil
}
if err == nil {
err = err1
}
}
if err == nil {
err = &os.PathError{Op: "stat", Path: path, Err: os.ErrNotExist}
}
return nil, err
}
func (ns NameSpace) Stat(path string) (os.FileInfo, error) {
return ns.stat(path, FileSystem.Stat)
}
func (ns NameSpace) Lstat(path string) (os.FileInfo, error) {
return ns.stat(path, FileSystem.Lstat)
}
// dirInfo is a trivial implementation of os.FileInfo for a directory.
type dirInfo string
func (d dirInfo) Name() string { return string(d) }
func (d dirInfo) Size() int64 { return 0 }
func (d dirInfo) Mode() os.FileMode { return os.ModeDir | 0555 }
func (d dirInfo) ModTime() time.Time { return startTime }
func (d dirInfo) IsDir() bool { return true }
func (d dirInfo) Sys() interface{} { return nil }
var startTime = time.Now()
// ReadDir implements the FileSystem ReadDir method. It's where most of the magic is.
// (The rest is in resolve.)
//
// Logically, ReadDir must return the union of all the directories that are named
// by path. In order to avoid misinterpreting Go packages, of all the directories
// that contain Go source code, we only include the files from the first,
// but we include subdirectories from all.
//
// ReadDir must also return directory entries needed to reach mount points.
// If the name space looks like the example in the type NameSpace comment,
// but c:\Go does not have a src/pkg subdirectory, we still want to be able
// to find that subdirectory, because we've mounted d:\Work1 and d:\Work2
// there. So if we don't see "src" in the directory listing for c:\Go, we add an
// entry for it before returning.
//
func (ns NameSpace) ReadDir(path string) ([]os.FileInfo, error) {
path = ns.clean(path)
var (
haveGo = false
haveName = map[string]bool{}
all []os.FileInfo
err error
first []os.FileInfo
)
for _, m := range ns.resolve(path) {
dir, err1 := m.fs.ReadDir(m.translate(path))
if err1 != nil {
if err == nil {
err = err1
}
continue
}
if dir == nil {
dir = []os.FileInfo{}
}
if first == nil {
first = dir
}
// If we don't yet have Go files in 'all' and this directory
// has some, add all the files from this directory.
// Otherwise, only add subdirectories.
useFiles := false
if !haveGo {
for _, d := range dir {
if strings.HasSuffix(d.Name(), ".go") {
useFiles = true
haveGo = true
break
}
}
}
for _, d := range dir {
name := d.Name()
if (d.IsDir() || useFiles) && !haveName[name] {
haveName[name] = true
all = append(all, d)
}
}
}
// We didn't find any directories containing Go files.
// If some directory returned successfully, use that.
if !haveGo {
for _, d := range first {
if !haveName[d.Name()] {
haveName[d.Name()] = true
all = append(all, d)
}
}
}
// Built union. Add any missing directories needed to reach mount points.
for old := range ns {
if hasPathPrefix(old, path) && old != path {
// Find next element after path in old.
elem := old[len(path):]
elem = strings.TrimPrefix(elem, "/")
if i := strings.Index(elem, "/"); i >= 0 {
elem = elem[:i]
}
if !haveName[elem] {
haveName[elem] = true
all = append(all, dirInfo(elem))
}
}
}
if len(all) == 0 {
return nil, err
}
sort.Sort(byName(all))
return all, nil
}
// RootType returns the RootType for the given path in the namespace.
func (ns NameSpace) RootType(path string) RootType {
// We resolve the given path to a list of mountedFS and then return
// the root type for the filesystem which contains the path.
for _, m := range ns.resolve(path) {
_, err := m.fs.ReadDir(m.translate(path))
// Found a match, return the filesystem's root type
if err == nil {
return m.fs.RootType(path)
}
}
return ""
}
// byName implements sort.Interface.
type byName []os.FileInfo
func (f byName) Len() int { return len(f) }
func (f byName) Less(i, j int) bool { return f[i].Name() < f[j].Name() }
func (f byName) Swap(i, j int) { f[i], f[j] = f[j], f[i] }