netbird/client/firewall/manager/firewall.go

191 lines
5.1 KiB
Go

package manager
import (
"crypto/sha256"
"encoding/hex"
"fmt"
"net"
"net/netip"
"sort"
"strings"
log "github.com/sirupsen/logrus"
"github.com/netbirdio/netbird/client/internal/statemanager"
)
const (
ForwardingFormatPrefix = "netbird-fwd-"
ForwardingFormat = "netbird-fwd-%s-%t"
PreroutingFormat = "netbird-prerouting-%s-%t"
NatFormat = "netbird-nat-%s-%t"
)
// Rule abstraction should be implemented by each firewall manager
//
// Each firewall type for different OS can use different type
// of the properties to hold data of the created rule
type Rule interface {
// GetRuleID returns the rule id
GetRuleID() string
}
// RuleDirection is the traffic direction which a rule is applied
type RuleDirection int
const (
// RuleDirectionIN applies to filters that handlers incoming traffic
RuleDirectionIN RuleDirection = iota
// RuleDirectionOUT applies to filters that handlers outgoing traffic
RuleDirectionOUT
)
// Action is the action to be taken on a rule
type Action int
const (
// ActionAccept is the action to accept a packet
ActionAccept Action = iota
// ActionDrop is the action to drop a packet
ActionDrop
)
// Manager is the high level abstraction of a firewall manager
//
// It declares methods which handle actions required by the
// Netbird client for ACL and routing functionality
type Manager interface {
Init(stateManager *statemanager.Manager) error
// AllowNetbird allows netbird interface traffic
AllowNetbird() error
// AddPeerFiltering adds a rule to the firewall
//
// If comment argument is empty firewall manager should set
// rule ID as comment for the rule
AddPeerFiltering(
ip net.IP,
proto Protocol,
sPort *Port,
dPort *Port,
direction RuleDirection,
action Action,
ipsetName string,
comment string,
) ([]Rule, error)
// DeletePeerRule from the firewall by rule definition
DeletePeerRule(rule Rule) error
// IsServerRouteSupported returns true if the firewall supports server side routing operations
IsServerRouteSupported() bool
AddRouteFiltering(source []netip.Prefix, destination netip.Prefix, proto Protocol, sPort *Port, dPort *Port, action Action) (Rule, error)
// DeleteRouteRule deletes a routing rule
DeleteRouteRule(rule Rule) error
// AddNatRule inserts a routing NAT rule
AddNatRule(pair RouterPair) error
// RemoveNatRule removes a routing NAT rule
RemoveNatRule(pair RouterPair) error
// SetLegacyManagement sets the legacy management mode
SetLegacyManagement(legacy bool) error
// Reset firewall to the default state
Reset(stateManager *statemanager.Manager) error
// Flush the changes to firewall controller
Flush() error
}
func GenKey(format string, pair RouterPair) string {
return fmt.Sprintf(format, pair.ID, pair.Inverse)
}
// LegacyManager defines the interface for legacy management operations
type LegacyManager interface {
RemoveAllLegacyRouteRules() error
GetLegacyManagement() bool
SetLegacyManagement(bool)
}
// SetLegacyManagement sets the route manager to use legacy management
func SetLegacyManagement(router LegacyManager, isLegacy bool) error {
oldLegacy := router.GetLegacyManagement()
if oldLegacy != isLegacy {
router.SetLegacyManagement(isLegacy)
log.Debugf("Set legacy management to %v", isLegacy)
}
// client reconnected to a newer mgmt, we need to clean up the legacy rules
if !isLegacy && oldLegacy {
if err := router.RemoveAllLegacyRouteRules(); err != nil {
return fmt.Errorf("remove legacy routing rules: %v", err)
}
log.Debugf("Legacy routing rules removed")
}
return nil
}
// GenerateSetName generates a unique name for an ipset based on the given sources.
func GenerateSetName(sources []netip.Prefix) string {
// sort for consistent naming
SortPrefixes(sources)
var sourcesStr strings.Builder
for _, src := range sources {
sourcesStr.WriteString(src.String())
}
hash := sha256.Sum256([]byte(sourcesStr.String()))
shortHash := hex.EncodeToString(hash[:])[:8]
return fmt.Sprintf("nb-%s", shortHash)
}
// MergeIPRanges merges overlapping IP ranges and returns a slice of non-overlapping netip.Prefix
func MergeIPRanges(prefixes []netip.Prefix) []netip.Prefix {
if len(prefixes) == 0 {
return prefixes
}
merged := []netip.Prefix{prefixes[0]}
for _, prefix := range prefixes[1:] {
last := merged[len(merged)-1]
if last.Contains(prefix.Addr()) {
// If the current prefix is contained within the last merged prefix, skip it
continue
}
if prefix.Contains(last.Addr()) {
// If the current prefix contains the last merged prefix, replace it
merged[len(merged)-1] = prefix
} else {
// Otherwise, add the current prefix to the merged list
merged = append(merged, prefix)
}
}
return merged
}
// SortPrefixes sorts the given slice of netip.Prefix in place.
// It sorts first by IP address, then by prefix length (most specific to least specific).
func SortPrefixes(prefixes []netip.Prefix) {
sort.Slice(prefixes, func(i, j int) bool {
addrCmp := prefixes[i].Addr().Compare(prefixes[j].Addr())
if addrCmp != 0 {
return addrCmp < 0
}
// If IP addresses are the same, compare prefix lengths (longer prefixes first)
return prefixes[i].Bits() > prefixes[j].Bits()
})
}