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package vault
import (
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"crypto/sha1"
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"encoding/json"
"errors"
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"fmt"
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"sort"
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"strings"
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"time"
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"github.com/hashicorp/go-uuid"
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"github.com/hashicorp/vault/helper/jsonutil"
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"github.com/hashicorp/vault/logical"
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)
const (
// coreMountConfigPath is used to store the mount configuration.
// Mounts are protected within the Vault itself, which means they
// can only be viewed or modified after an unseal.
coreMountConfigPath = "core/mounts"
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// coreLocalMountConfigPath is used to store mount configuration for local
// (non-replicated) mounts
coreLocalMountConfigPath = "core/local-mounts"
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// backendBarrierPrefix is the prefix to the UUID used in the
// barrier view for the backends.
backendBarrierPrefix = "logical/"
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// systemBarrierPrefix is the prefix used for the
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// system logical backend.
systemBarrierPrefix = "sys/"
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// mountTableType is the value we expect to find for the mount table and
// corresponding entries
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mountTableType = "mounts"
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)
var (
// loadMountsFailed if loadMounts encounters an error
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errLoadMountsFailed = errors . New ( "failed to setup mount table" )
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// protectedMounts cannot be remounted
protectedMounts = [ ] string {
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"audit/" ,
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"auth/" ,
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"sys/" ,
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"cubbyhole/" ,
}
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untunableMounts = [ ] string {
"cubbyhole/" ,
"sys/" ,
"audit/" ,
}
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// singletonMounts can only exist in one location and are
// loaded by default. These are types, not paths.
singletonMounts = [ ] string {
"cubbyhole" ,
"system" ,
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}
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)
// MountTable is used to represent the internal mount table
type MountTable struct {
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Type string ` json:"type" `
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Entries [ ] * MountEntry ` json:"entries" `
}
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// shallowClone returns a copy of the mount table that
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// keeps the MountEntry locations, so as not to invalidate
// other locations holding pointers. Care needs to be taken
// if modifying entries rather than modifying the table itself
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func ( t * MountTable ) shallowClone ( ) * MountTable {
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mt := & MountTable {
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Type : t . Type ,
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Entries : make ( [ ] * MountEntry , len ( t . Entries ) ) ,
}
for i , e := range t . Entries {
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mt . Entries [ i ] = e
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}
return mt
}
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// Hash is used to generate a hash value for the mount table
func ( t * MountTable ) Hash ( ) ( [ ] byte , error ) {
buf , err := json . Marshal ( t )
if err != nil {
return nil , err
}
hash := sha1 . Sum ( buf )
return hash [ : ] , nil
}
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// setTaint is used to set the taint on given entry
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func ( t * MountTable ) setTaint ( path string , value bool ) * MountEntry {
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n := len ( t . Entries )
for i := 0 ; i < n ; i ++ {
if t . Entries [ i ] . Path == path {
t . Entries [ i ] . Tainted = value
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return t . Entries [ i ]
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}
}
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return nil
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}
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// remove is used to remove a given path entry; returns the entry that was
// removed
func ( t * MountTable ) remove ( path string ) * MountEntry {
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n := len ( t . Entries )
for i := 0 ; i < n ; i ++ {
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if entry := t . Entries [ i ] ; entry . Path == path {
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t . Entries [ i ] , t . Entries [ n - 1 ] = t . Entries [ n - 1 ] , nil
t . Entries = t . Entries [ : n - 1 ]
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return entry
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}
}
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return nil
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}
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// sortEntriesByPath sorts the entries in the table by path and returns the
// table; this is useful for tests
func ( t * MountTable ) sortEntriesByPath ( ) * MountTable {
sort . Slice ( t . Entries , func ( i , j int ) bool {
return t . Entries [ i ] . Path < t . Entries [ j ] . Path
} )
return t
}
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// MountEntry is used to represent a mount table entry
type MountEntry struct {
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Table string ` json:"table" ` // The table it belongs to
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Path string ` json:"path" ` // Mount Path
Type string ` json:"type" ` // Logical backend Type
Description string ` json:"description" ` // User-provided description
UUID string ` json:"uuid" ` // Barrier view UUID
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Config MountConfig ` json:"config" ` // Configuration related to this mount (but not backend-derived)
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Options map [ string ] string ` json:"options" ` // Backend options
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Local bool ` json:"local" ` // Local mounts are not replicated or affected by replication
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Tainted bool ` json:"tainted,omitempty" ` // Set as a Write-Ahead flag for unmount/remount
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}
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// MountConfig is used to hold settable options
type MountConfig struct {
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DefaultLeaseTTL time . Duration ` json:"default_lease_ttl" structs:"default_lease_ttl" mapstructure:"default_lease_ttl" ` // Override for global default
MaxLeaseTTL time . Duration ` json:"max_lease_ttl" structs:"max_lease_ttl" mapstructure:"max_lease_ttl" ` // Override for global default
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}
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// Returns a deep copy of the mount entry
func ( e * MountEntry ) Clone ( ) * MountEntry {
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optClone := make ( map [ string ] string )
for k , v := range e . Options {
optClone [ k ] = v
}
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return & MountEntry {
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Table : e . Table ,
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Path : e . Path ,
Type : e . Type ,
Description : e . Description ,
UUID : e . UUID ,
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Config : e . Config ,
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Options : optClone ,
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Local : e . Local ,
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Tainted : e . Tainted ,
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}
}
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
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// Mount is used to mount a new backend to the mount table.
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func ( c * Core ) mount ( entry * MountEntry ) error {
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// Ensure we end the path in a slash
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if ! strings . HasSuffix ( entry . Path , "/" ) {
entry . Path += "/"
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}
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// Prevent protected paths from being mounted
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for _ , p := range protectedMounts {
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if strings . HasPrefix ( entry . Path , p ) {
return logical . CodedError ( 403 , fmt . Sprintf ( "cannot mount '%s'" , entry . Path ) )
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}
}
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// Do not allow more than one instance of a singleton mount
for _ , p := range singletonMounts {
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if entry . Type == p {
return logical . CodedError ( 403 , fmt . Sprintf ( "Cannot mount more than one instance of '%s'" , entry . Type ) )
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}
}
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c . mountsLock . Lock ( )
defer c . mountsLock . Unlock ( )
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// Verify there is no conflicting mount
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if match := c . router . MatchingMount ( entry . Path ) ; match != "" {
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return logical . CodedError ( 409 , fmt . Sprintf ( "existing mount at %s" , match ) )
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}
// Generate a new UUID and view
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if entry . UUID == "" {
entryUUID , err := uuid . GenerateUUID ( )
if err != nil {
return err
}
entry . UUID = entryUUID
}
viewPath := backendBarrierPrefix + entry . UUID + "/"
view := NewBarrierView ( c . barrier , viewPath )
sysView := c . mountEntrySysView ( entry )
backend , err := c . newLogicalBackend ( entry . Type , sysView , view , nil )
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if err != nil {
return err
}
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// Call initialize; this takes care of init tasks that must be run after
// the ignore paths are collected
if err := backend . Initialize ( ) ; err != nil {
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return err
}
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newTable := c . mounts . shallowClone ( )
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newTable . Entries = append ( newTable . Entries , entry )
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if err := c . persistMounts ( newTable , entry . Local ) ; err != nil {
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c . logger . Error ( "core: failed to update mount table" , "error" , err )
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return logical . CodedError ( 500 , "failed to update mount table" )
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}
c . mounts = newTable
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if err := c . router . Mount ( backend , entry . Path , entry , view ) ; err != nil {
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return err
}
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if c . logger . IsInfo ( ) {
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c . logger . Info ( "core: successful mount" , "path" , entry . Path , "type" , entry . Type )
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}
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return nil
}
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// Unmount is used to unmount a path. The boolean indicates whether the mount
// was found.
func ( c * Core ) unmount ( path string ) ( bool , error ) {
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// Ensure we end the path in a slash
if ! strings . HasSuffix ( path , "/" ) {
path += "/"
}
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// Prevent protected paths from being unmounted
for _ , p := range protectedMounts {
if strings . HasPrefix ( path , p ) {
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return true , fmt . Errorf ( "cannot unmount '%s'" , path )
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}
}
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// Verify exact match of the route
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match := c . router . MatchingMount ( path )
if match == "" || path != match {
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return false , fmt . Errorf ( "no matching mount" )
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}
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// Get the view for this backend
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view := c . router . MatchingStorageView ( path )
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// Mark the entry as tainted
if err := c . taintMountEntry ( path ) ; err != nil {
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return true , err
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}
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// Taint the router path to prevent routing. Note that in-flight requests
// are uncertain, right now.
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if err := c . router . Taint ( path ) ; err != nil {
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return true , err
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}
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// Invoke the rollback manager a final time
if err := c . rollback . Rollback ( path ) ; err != nil {
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return true , err
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}
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// Revoke all the dynamic keys
if err := c . expiration . RevokePrefix ( path ) ; err != nil {
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return true , err
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}
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// Call cleanup function if it exists
b , ok := c . router . root . Get ( path )
if ok {
b . ( * routeEntry ) . backend . Cleanup ( )
}
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// Unmount the backend entirely
if err := c . router . Unmount ( path ) ; err != nil {
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return true , err
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}
// Clear the data in the view
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if err := logical . ClearView ( view ) ; err != nil {
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return true , err
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}
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// Remove the mount table entry
if err := c . removeMountEntry ( path ) ; err != nil {
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return true , err
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}
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if c . logger . IsInfo ( ) {
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c . logger . Info ( "core: successfully unmounted" , "path" , path )
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}
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return true , nil
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}
// removeMountEntry is used to remove an entry from the mount table
func ( c * Core ) removeMountEntry ( path string ) error {
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c . mountsLock . Lock ( )
defer c . mountsLock . Unlock ( )
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// Remove the entry from the mount table
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newTable := c . mounts . shallowClone ( )
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entry := newTable . remove ( path )
if entry == nil {
c . logger . Error ( "core: nil entry found removing entry in mounts table" , "path" , path )
return logical . CodedError ( 500 , "failed to remove entry in mounts table" )
}
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// When unmounting all entries the JSON code will load back up from storage
// as a nil slice, which kills tests...just set it nil explicitly
if len ( newTable . Entries ) == 0 {
newTable . Entries = nil
}
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// Update the mount table
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if err := c . persistMounts ( newTable , entry . Local ) ; err != nil {
c . logger . Error ( "core: failed to remove entry from mounts table" , "error" , err )
return logical . CodedError ( 500 , "failed to remove entry from mounts table" )
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}
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c . mounts = newTable
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return nil
}
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// taintMountEntry is used to mark an entry in the mount table as tainted
func ( c * Core ) taintMountEntry ( path string ) error {
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c . mountsLock . Lock ( )
defer c . mountsLock . Unlock ( )
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// As modifying the taint of an entry affects shallow clones,
// we simply use the original
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entry := c . mounts . setTaint ( path , true )
if entry == nil {
c . logger . Error ( "core: nil entry found tainting entry in mounts table" , "path" , path )
return logical . CodedError ( 500 , "failed to taint entry in mounts table" )
}
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// Update the mount table
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if err := c . persistMounts ( c . mounts , entry . Local ) ; err != nil {
c . logger . Error ( "core: failed to taint entry in mounts table" , "error" , err )
return logical . CodedError ( 500 , "failed to taint entry in mounts table" )
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}
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return nil
}
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
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// Remount is used to remount a path at a new mount point.
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func ( c * Core ) remount ( src , dst string ) error {
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// Ensure we end the path in a slash
if ! strings . HasSuffix ( src , "/" ) {
src += "/"
}
if ! strings . HasSuffix ( dst , "/" ) {
dst += "/"
}
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// Prevent protected paths from being remounted
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for _ , p := range protectedMounts {
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if strings . HasPrefix ( src , p ) {
return fmt . Errorf ( "cannot remount '%s'" , src )
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}
}
// Verify exact match of the route
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match := c . router . MatchingMount ( src )
if match == "" || src != match {
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return fmt . Errorf ( "no matching mount at '%s'" , src )
}
if match := c . router . MatchingMount ( dst ) ; match != "" {
return fmt . Errorf ( "existing mount at '%s'" , match )
}
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// Mark the entry as tainted
if err := c . taintMountEntry ( src ) ; err != nil {
return err
}
// Taint the router path to prevent routing
if err := c . router . Taint ( src ) ; err != nil {
return err
}
// Invoke the rollback manager a final time
if err := c . rollback . Rollback ( src ) ; err != nil {
return err
}
// Revoke all the dynamic keys
if err := c . expiration . RevokePrefix ( src ) ; err != nil {
return err
}
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c . mountsLock . Lock ( )
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var ent * MountEntry
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for _ , ent = range c . mounts . Entries {
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if ent . Path == src {
ent . Path = dst
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ent . Tainted = false
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break
}
}
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if ent == nil {
c . logger . Error ( "core: failed to find entry in mounts table" )
return logical . CodedError ( 500 , "failed to find entry in mounts table" )
}
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// Update the mount table
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if err := c . persistMounts ( c . mounts , ent . Local ) ; err != nil {
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ent . Path = src
ent . Tainted = true
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c . mountsLock . Unlock ( )
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c . logger . Error ( "core: failed to update mounts table" , "error" , err )
return logical . CodedError ( 500 , "failed to update mounts table" )
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}
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c . mountsLock . Unlock ( )
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// Remount the backend
if err := c . router . Remount ( src , dst ) ; err != nil {
return err
}
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// Un-taint the path
if err := c . router . Untaint ( dst ) ; err != nil {
return err
}
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if c . logger . IsInfo ( ) {
c . logger . Info ( "core: successful remount" , "old_path" , src , "new_path" , dst )
}
2015-03-12 19:09:30 +00:00
return nil
}
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
// loadMounts is invoked as part of postUnseal to load the mount table
func ( c * Core ) loadMounts ( ) error {
2015-11-11 16:44:07 +00:00
mountTable := & MountTable { }
2017-02-17 01:13:19 +00:00
localMountTable := & MountTable { }
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
// Load the existing mount table
raw , err := c . barrier . Get ( coreMountConfigPath )
if err != nil {
2016-08-19 20:45:17 +00:00
c . logger . Error ( "core: failed to read mount table" , "error" , err )
2015-08-28 21:25:09 +00:00
return errLoadMountsFailed
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
}
2017-02-17 01:13:19 +00:00
rawLocal , err := c . barrier . Get ( coreLocalMountConfigPath )
if err != nil {
c . logger . Error ( "core: failed to read local mount table" , "error" , err )
return errLoadMountsFailed
}
2015-11-11 16:44:07 +00:00
c . mountsLock . Lock ( )
defer c . mountsLock . Unlock ( )
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
if raw != nil {
2016-08-04 21:20:37 +00:00
// Check if the persisted value has canary in the beginning. If
// yes, decompress the table and then JSON decode it. If not,
// simply JSON decode it.
2016-08-09 14:33:41 +00:00
if err := jsonutil . DecodeJSON ( raw . Value , mountTable ) ; err != nil {
2016-08-19 20:45:17 +00:00
c . logger . Error ( "core: failed to decompress and/or decode the mount table" , "error" , err )
2016-08-04 21:20:37 +00:00
return err
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
}
2015-11-11 16:44:07 +00:00
c . mounts = mountTable
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
}
2017-02-17 01:13:19 +00:00
if rawLocal != nil {
if err := jsonutil . DecodeJSON ( rawLocal . Value , localMountTable ) ; err != nil {
c . logger . Error ( "core: failed to decompress and/or decode the local mount table" , "error" , err )
return err
}
c . mounts . Entries = append ( c . mounts . Entries , localMountTable . Entries ... )
}
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
2015-09-21 21:54:36 +00:00
// Ensure that required entries are loaded, or new ones
// added may never get loaded at all. Note that this
// is only designed to work with singletons, as it checks
// by type only.
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
if c . mounts != nil {
2015-09-21 21:54:36 +00:00
needPersist := false
2016-05-26 16:55:00 +00:00
// Upgrade to typed mount table
if c . mounts . Type == "" {
c . mounts . Type = mountTableType
needPersist = true
}
2015-09-21 21:54:36 +00:00
for _ , requiredMount := range requiredMountTable ( ) . Entries {
foundRequired := false
for _ , coreMount := range c . mounts . Entries {
if coreMount . Type == requiredMount . Type {
foundRequired = true
break
}
}
if ! foundRequired {
c . mounts . Entries = append ( c . mounts . Entries , requiredMount )
needPersist = true
}
}
2016-05-26 16:55:00 +00:00
// Upgrade to table-scoped entries
for _ , entry := range c . mounts . Entries {
2017-02-24 15:05:44 +00:00
if entry . Type == "cubbyhole" && ! entry . Local {
entry . Local = true
needPersist = true
}
2016-05-26 16:55:00 +00:00
if entry . Table == "" {
entry . Table = c . mounts . Type
needPersist = true
}
}
2015-09-21 21:54:36 +00:00
// Done if we have restored the mount table and we don't need
// to persist
if ! needPersist {
return nil
}
} else {
// Create and persist the default mount table
c . mounts = defaultMountTable ( )
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
}
2017-03-02 19:37:59 +00:00
if err := c . persistMounts ( c . mounts , false ) ; err != nil {
2017-01-12 01:21:34 +00:00
c . logger . Error ( "core: failed to persist mount table" , "error" , err )
2015-08-28 21:25:09 +00:00
return errLoadMountsFailed
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
}
return nil
}
// persistMounts is used to persist the mount table after modification
2017-03-02 19:37:59 +00:00
func ( c * Core ) persistMounts ( table * MountTable , localOnly bool ) error {
2016-05-26 16:55:00 +00:00
if table . Type != mountTableType {
2016-08-19 20:45:17 +00:00
c . logger . Error ( "core: given table to persist has wrong type" , "actual_type" , table . Type , "expected_type" , mountTableType )
2016-05-26 16:55:00 +00:00
return fmt . Errorf ( "invalid table type given, not persisting" )
}
for _ , entry := range table . Entries {
if entry . Table != table . Type {
2016-08-19 20:45:17 +00:00
c . logger . Error ( "core: given entry to persist in mount table has wrong table value" , "path" , entry . Path , "entry_table_type" , entry . Table , "actual_type" , table . Type )
2016-05-26 16:55:00 +00:00
return fmt . Errorf ( "invalid mount entry found, not persisting" )
}
}
2017-02-17 01:13:19 +00:00
nonLocalMounts := & MountTable {
Type : mountTableType ,
}
localMounts := & MountTable {
Type : mountTableType ,
}
for _ , entry := range table . Entries {
if entry . Local {
localMounts . Entries = append ( localMounts . Entries , entry )
} else {
nonLocalMounts . Entries = append ( nonLocalMounts . Entries , entry )
}
}
2017-03-02 19:37:59 +00:00
if ! localOnly {
// Encode the mount table into JSON and compress it (lzw).
compressedBytes , err := jsonutil . EncodeJSONAndCompress ( nonLocalMounts , nil )
if err != nil {
c . logger . Error ( "core: failed to encode and/or compress the mount table" , "error" , err )
return err
}
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
2017-03-02 19:37:59 +00:00
// Create an entry
entry := & Entry {
Key : coreMountConfigPath ,
Value : compressedBytes ,
}
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
2017-03-02 19:37:59 +00:00
// Write to the physical backend
if err := c . barrier . Put ( entry ) ; err != nil {
c . logger . Error ( "core: failed to persist mount table" , "error" , err )
return err
}
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
}
2017-02-17 01:13:19 +00:00
// Repeat with local mounts
2017-03-02 19:37:59 +00:00
compressedBytes , err := jsonutil . EncodeJSONAndCompress ( localMounts , nil )
2017-02-17 01:13:19 +00:00
if err != nil {
c . logger . Error ( "core: failed to encode and/or compress the local mount table" , "error" , err )
return err
}
2017-03-02 19:37:59 +00:00
entry := & Entry {
2017-02-17 01:13:19 +00:00
Key : coreLocalMountConfigPath ,
Value : compressedBytes ,
}
if err := c . barrier . Put ( entry ) ; err != nil {
c . logger . Error ( "core: failed to persist local mount table" , "error" , err )
return err
}
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
return nil
}
// setupMounts is invoked after we've loaded the mount table to
// initialize the logical backends and setup the router
func ( c * Core ) setupMounts ( ) error {
2015-11-11 16:44:07 +00:00
c . mountsLock . Lock ( )
defer c . mountsLock . Unlock ( )
2015-03-15 21:53:41 +00:00
var backend logical . Backend
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
var view * BarrierView
2015-09-04 20:58:12 +00:00
var err error
2015-11-11 16:44:07 +00:00
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
for _ , entry := range c . mounts . Entries {
// Initialize the backend, special casing for system
2015-04-02 00:24:22 +00:00
barrierPath := backendBarrierPrefix + entry . UUID + "/"
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
if entry . Type == "system" {
2015-04-02 00:24:22 +00:00
barrierPath = systemBarrierPrefix
2015-03-15 23:25:38 +00:00
}
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
2015-07-01 00:30:43 +00:00
// Create a barrier view using the UUID
view = NewBarrierView ( c . barrier , barrierPath )
2017-02-17 01:13:19 +00:00
sysView := c . mountEntrySysView ( entry )
2015-07-01 00:30:43 +00:00
// Initialize the backend
2015-08-28 21:25:09 +00:00
// Create the new backend
2017-02-17 01:13:19 +00:00
backend , err = c . newLogicalBackend ( entry . Type , sysView , view , nil )
2015-03-15 23:25:38 +00:00
if err != nil {
2016-08-19 20:45:17 +00:00
c . logger . Error ( "core: failed to create mount entry" , "path" , entry . Path , "error" , err )
2015-08-28 21:25:09 +00:00
return errLoadMountsFailed
2015-03-15 23:25:38 +00:00
}
2017-02-17 01:13:19 +00:00
if err := backend . Initialize ( ) ; err != nil {
return err
}
2015-09-15 17:49:53 +00:00
switch entry . Type {
case "system" :
2015-09-04 20:58:12 +00:00
c . systemBarrierView = view
2015-09-15 17:49:53 +00:00
case "cubbyhole" :
ch := backend . ( * CubbyholeBackend )
ch . saltUUID = entry . UUID
ch . storageView = view
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
}
// Mount the backend
2015-09-04 20:58:12 +00:00
err = c . router . Mount ( backend , entry . Path , entry , view )
2015-03-15 23:25:38 +00:00
if err != nil {
2016-08-19 20:45:17 +00:00
c . logger . Error ( "core: failed to mount entry" , "path" , entry . Path , "error" , err )
2015-08-28 21:25:09 +00:00
return errLoadMountsFailed
2015-09-21 21:54:36 +00:00
} else {
2016-08-19 20:45:17 +00:00
if c . logger . IsInfo ( ) {
c . logger . Info ( "core: successfully mounted backend" , "type" , entry . Type , "path" , entry . Path )
}
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
}
2015-04-02 18:17:55 +00:00
// Ensure the path is tainted if set in the mount table
if entry . Tainted {
c . router . Taint ( entry . Path )
}
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
}
return nil
}
// unloadMounts is used before we seal the vault to reset the mounts to
2015-09-10 14:11:37 +00:00
// their unloaded state, calling Cleanup if defined. This is reversed by load and setup mounts.
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
func ( c * Core ) unloadMounts ( ) error {
2015-11-11 16:44:07 +00:00
c . mountsLock . Lock ( )
defer c . mountsLock . Unlock ( )
2015-09-10 14:11:37 +00:00
if c . mounts != nil {
2016-09-13 15:50:14 +00:00
mountTable := c . mounts . shallowClone ( )
2015-11-11 16:44:07 +00:00
for _ , e := range mountTable . Entries {
2015-09-10 14:11:37 +00:00
prefix := e . Path
b , ok := c . router . root . Get ( prefix )
if ok {
2015-09-11 10:40:31 +00:00
b . ( * routeEntry ) . backend . Cleanup ( )
2015-09-10 14:11:37 +00:00
}
}
}
2015-11-11 16:44:07 +00:00
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
c . mounts = nil
c . router = NewRouter ( )
2015-09-04 20:58:12 +00:00
c . systemBarrierView = nil
vault: make Mount related core functions public
/cc @armon - So I know the conversation we had related to this about
auth, but I think we still need to export these and do auth only at the
external API layer. If you're writing to the internal API, then all bets
are off.
The reason is simply that if you have access to the code, you can
already work around it anyways (you can disable auth or w/e), so a
compromised Vault source/binary is already a failure, and that is the
only thing that our previous unexported methods were protecting against.
If you write an external tool to access a Vault, it still needs to be
unsealed so _that_ is the primary security mechanism from an API
perspective. Once it is unsealed then the core API has full access to
the Vault, and identity/auth is only done at the external API layer, not
at the internal API layer.
The benefits of this approach is that it lets us still treat the "sys"
mount specially but at least have sys adopt helper/backend and use that
machinery and it can still be the only backend which actually has a
reference to *vault.Core to do core things (a key difference). So, an
AWS backend still will never be able to muck with things it can't, but
we're explicitly giving Sys (via struct initialization in Go itself)
a reference to *vault.Core.
2015-03-15 00:26:59 +00:00
return nil
}
2015-03-18 22:46:07 +00:00
// newLogicalBackend is used to create and configure a new logical backend by name
2015-08-28 21:25:09 +00:00
func ( c * Core ) newLogicalBackend ( t string , sysView logical . SystemView , view logical . Storage , conf map [ string ] string ) ( logical . Backend , error ) {
2015-03-18 22:21:41 +00:00
f , ok := c . logicalBackends [ t ]
2015-03-15 23:25:38 +00:00
if ! ok {
return nil , fmt . Errorf ( "unknown backend type: %s" , t )
}
2015-07-01 00:30:43 +00:00
config := & logical . BackendConfig {
2015-09-09 19:42:29 +00:00
StorageView : view ,
Logger : c . logger ,
Config : conf ,
2015-09-10 01:58:09 +00:00
System : sysView ,
2015-07-01 00:30:43 +00:00
}
b , err := f ( config )
2015-04-04 18:39:58 +00:00
if err != nil {
return nil , err
}
return b , nil
2015-03-15 23:25:38 +00:00
}
2015-09-02 19:56:58 +00:00
// mountEntrySysView creates a logical.SystemView from global and
2015-09-04 20:58:12 +00:00
// mount-specific entries; because this should be called when setting
// up a mountEntry, it doesn't check to ensure that me is not nil
2017-02-17 01:13:19 +00:00
func ( c * Core ) mountEntrySysView ( entry * MountEntry ) logical . SystemView {
2015-09-04 20:58:12 +00:00
return dynamicSystemView {
2015-09-10 02:17:49 +00:00
core : c ,
2017-02-17 01:13:19 +00:00
mountEntry : entry ,
2015-08-28 21:25:09 +00:00
}
}
2015-03-11 22:19:41 +00:00
// defaultMountTable creates a default mount table
func defaultMountTable ( ) * MountTable {
2016-05-26 16:55:00 +00:00
table := & MountTable {
Type : mountTableType ,
}
2016-01-13 18:40:08 +00:00
mountUUID , err := uuid . GenerateUUID ( )
if err != nil {
panic ( fmt . Sprintf ( "could not create default mount table UUID: %v" , err ) )
}
2015-03-11 22:19:41 +00:00
genericMount := & MountEntry {
2016-05-26 16:55:00 +00:00
Table : mountTableType ,
2015-03-11 22:19:41 +00:00
Path : "secret/" ,
Type : "generic" ,
Description : "generic secret storage" ,
2016-01-13 18:40:08 +00:00
UUID : mountUUID ,
2015-03-11 22:19:41 +00:00
}
2015-09-21 21:54:36 +00:00
table . Entries = append ( table . Entries , genericMount )
table . Entries = append ( table . Entries , requiredMountTable ( ) . Entries ... )
return table
}
// requiredMountTable() creates a mount table with entries required
// to be available
func requiredMountTable ( ) * MountTable {
2016-05-26 16:55:00 +00:00
table := & MountTable {
Type : mountTableType ,
}
2016-01-13 18:40:08 +00:00
cubbyholeUUID , err := uuid . GenerateUUID ( )
if err != nil {
panic ( fmt . Sprintf ( "could not create cubbyhole UUID: %v" , err ) )
}
2015-09-10 01:58:09 +00:00
cubbyholeMount := & MountEntry {
2016-05-26 16:55:00 +00:00
Table : mountTableType ,
2015-09-10 01:58:09 +00:00
Path : "cubbyhole/" ,
Type : "cubbyhole" ,
Description : "per-token private secret storage" ,
2016-01-13 18:40:08 +00:00
UUID : cubbyholeUUID ,
2017-02-18 18:51:05 +00:00
Local : true ,
2016-01-13 18:40:08 +00:00
}
sysUUID , err := uuid . GenerateUUID ( )
if err != nil {
panic ( fmt . Sprintf ( "could not create sys UUID: %v" , err ) )
2015-09-10 01:58:09 +00:00
}
2015-03-11 22:19:41 +00:00
sysMount := & MountEntry {
2016-05-26 16:55:00 +00:00
Table : mountTableType ,
2015-03-11 22:19:41 +00:00
Path : "sys/" ,
Type : "system" ,
Description : "system endpoints used for control, policy and debugging" ,
2016-01-13 18:40:08 +00:00
UUID : sysUUID ,
2015-03-11 22:19:41 +00:00
}
2015-09-10 01:58:09 +00:00
table . Entries = append ( table . Entries , cubbyholeMount )
2015-03-11 22:19:41 +00:00
table . Entries = append ( table . Entries , sysMount )
return table
}