remove sigManager, it seems safer to just burn the CPU than to store a map of strings of potentially arbitrary length

This commit is contained in:
Arceliar 2018-11-25 13:06:54 -06:00
parent 4e156bd4f7
commit 9046dbde4f
4 changed files with 1 additions and 99 deletions

View File

@ -22,7 +22,6 @@ type Core struct {
sigPriv sigPrivKey sigPriv sigPrivKey
switchTable switchTable switchTable switchTable
peers peers peers peers
sigs sigManager
sessions sessions sessions sessions
router router router router
dht dht dht dht
@ -50,7 +49,6 @@ func (c *Core) init(bpub *boxPubKey,
c.boxPub, c.boxPriv = *bpub, *bpriv c.boxPub, c.boxPriv = *bpub, *bpriv
c.sigPub, c.sigPriv = *spub, *spriv c.sigPub, c.sigPriv = *spub, *spriv
c.admin.core = c c.admin.core = c
c.sigs.init()
c.searches.init(c) c.searches.init(c)
c.dht.init(c) c.dht.init(c)
c.sessions.init(c) c.sessions.init(c)

View File

@ -316,7 +316,7 @@ func (p *peer) handleSwitchMsg(packet []byte) {
sigMsg.Hops = msg.Hops[:idx] sigMsg.Hops = msg.Hops[:idx]
loc.coords = append(loc.coords, hop.Port) loc.coords = append(loc.coords, hop.Port)
bs := getBytesForSig(&hop.Next, &sigMsg) bs := getBytesForSig(&hop.Next, &sigMsg)
if !p.core.sigs.check(&prevKey, &hop.Sig, bs) { if !verify(&prevKey, bs, &hop.Sig) {
p.core.peers.removePeer(p.port) p.core.peers.removePeer(p.port)
} }
prevKey = hop.Next prevKey = hop.Next

View File

@ -121,7 +121,6 @@ func (r *router) mainLoop() {
r.core.switchTable.doMaintenance() r.core.switchTable.doMaintenance()
r.core.dht.doMaintenance() r.core.dht.doMaintenance()
r.core.sessions.cleanup() r.core.sessions.cleanup()
r.core.sigs.cleanup()
util_getBytes() // To slowly drain things util_getBytes() // To slowly drain things
} }
case f := <-r.admin: case f := <-r.admin:

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@ -1,95 +0,0 @@
package yggdrasil
// This is where we record which signatures we've previously checked
// It's so we can avoid needlessly checking them again
import (
"sync"
"time"
)
// This keeps track of what signatures have already been checked.
// It's used to skip expensive crypto operations, given that many signatures are likely to be the same for the average node's peers.
type sigManager struct {
mutex sync.RWMutex
checked map[sigBytes]knownSig
lastCleaned time.Time
}
// Represents a known signature.
// Includes the key, the signature bytes, the bytes that were signed, and the time it was last used.
type knownSig struct {
key sigPubKey
sig sigBytes
bs []byte
time time.Time
}
// Initializes the signature manager.
func (m *sigManager) init() {
m.checked = make(map[sigBytes]knownSig)
}
// Checks if a key and signature match the supplied bytes.
// If the same key/sig/bytes have been checked before, it returns true from the cached results.
// If not, it checks the key, updates it in the cache if successful, and returns the checked results.
func (m *sigManager) check(key *sigPubKey, sig *sigBytes, bs []byte) bool {
if m.isChecked(key, sig, bs) {
return true
}
verified := verify(key, bs, sig)
if verified {
m.putChecked(key, sig, bs)
}
return verified
}
// Checks the cache to see if this key/sig/bytes combination has already been verified.
// Returns true if it finds a match.
func (m *sigManager) isChecked(key *sigPubKey, sig *sigBytes, bs []byte) bool {
m.mutex.RLock()
defer m.mutex.RUnlock()
k, isIn := m.checked[*sig]
if !isIn {
return false
}
if k.key != *key || k.sig != *sig || len(bs) != len(k.bs) {
return false
}
for idx := 0; idx < len(bs); idx++ {
if bs[idx] != k.bs[idx] {
return false
}
}
k.time = time.Now()
return true
}
// Puts a new result into the cache.
// This result is then used by isChecked to skip the expensive crypto verification if it's needed again.
// This is useful because, for nodes with multiple peers, there is often a lot of overlap between the signatures provided by each peer.
func (m *sigManager) putChecked(key *sigPubKey, newsig *sigBytes, bs []byte) {
m.mutex.Lock()
defer m.mutex.Unlock()
k := knownSig{key: *key, sig: *newsig, bs: bs, time: time.Now()}
m.checked[*newsig] = k
}
func (m *sigManager) cleanup() {
m.mutex.Lock()
defer m.mutex.Unlock()
if time.Since(m.lastCleaned) < time.Minute {
return
}
for s, k := range m.checked {
if time.Since(k.time) > time.Minute {
delete(m.checked, s)
}
}
newChecked := make(map[sigBytes]knownSig, len(m.checked))
for s, k := range m.checked {
newChecked[s] = k
}
m.checked = newChecked
m.lastCleaned = time.Now()
}