diff --git a/go.mod b/go.mod
index d28bb37..0a230b1 100644
--- a/go.mod
+++ b/go.mod
@@ -4,6 +4,7 @@ go 1.25
 
 require (
 	github.com/docker/docker v28.5.2+incompatible
+	github.com/gaissmai/bart v0.26.0
 	github.com/gorilla/websocket v1.5.3
 	github.com/prometheus/client_golang v1.23.2
 	github.com/vishvananda/netlink v1.3.1
diff --git a/go.sum b/go.sum
index dc35871..bd5624e 100644
--- a/go.sum
+++ b/go.sum
@@ -26,6 +26,8 @@ github.com/docker/go-units v0.4.0 h1:3uh0PgVws3nIA0Q+MwDC8yjEPf9zjRfZZWXZYDct3Tw
 github.com/docker/go-units v0.4.0/go.mod h1:fgPhTUdO+D/Jk86RDLlptpiXQzgHJF7gydDDbaIK4Dk=
 github.com/felixge/httpsnoop v1.0.4 h1:NFTV2Zj1bL4mc9sqWACXbQFVBBg2W3GPvqp8/ESS2Wg=
 github.com/felixge/httpsnoop v1.0.4/go.mod h1:m8KPJKqk1gH5J9DgRY2ASl2lWCfGKXixSwevea8zH2U=
+github.com/gaissmai/bart v0.26.0 h1:xOZ57E9hJLBiQaSyeZa9wgWhGuzfGACgqp4BE77OkO0=
+github.com/gaissmai/bart v0.26.0/go.mod h1:GREWQfTLRWz/c5FTOsIw+KkscuFkIV5t8Rp7Nd1Td5c=
 github.com/go-logr/logr v1.2.2/go.mod h1:jdQByPbusPIv2/zmleS9BjJVeZ6kBagPoEUsqbVz/1A=
 github.com/go-logr/logr v1.4.3 h1:CjnDlHq8ikf6E492q6eKboGOC0T8CDaOvkHCIg8idEI=
 github.com/go-logr/logr v1.4.3/go.mod h1:9T104GzyrTigFIr8wt5mBrctHMim0Nb2HLGrmQ40KvY=
diff --git a/netstack2/proxy.go b/netstack2/proxy.go
index 4583529..46dfaa1 100644
--- a/netstack2/proxy.go
+++ b/netstack2/proxy.go
@@ -48,115 +48,6 @@ type SubnetRule struct {
 	PortRanges   []PortRange  // empty slice means all ports allowed
 }
 
-// ruleKey is used as a map key for fast O(1) lookups
-type ruleKey struct {
-	sourcePrefix string
-	destPrefix   string
-}
-
-// SubnetLookup provides fast IP subnet and port matching with O(1) lookup performance
-type SubnetLookup struct {
-	mu    sync.RWMutex
-	rules map[ruleKey]*SubnetRule // Map for O(1) lookups by prefix combination
-}
-
-// NewSubnetLookup creates a new subnet lookup table
-func NewSubnetLookup() *SubnetLookup {
-	return &SubnetLookup{
-		rules: make(map[ruleKey]*SubnetRule),
-	}
-}
-
-// AddSubnet adds a subnet rule with source and destination prefixes and optional port restrictions
-// If portRanges is nil or empty, all ports are allowed for this subnet
-// rewriteTo can be either an IP/CIDR (e.g., "192.168.1.1/32") or a domain name (e.g., "example.com")
-func (sl *SubnetLookup) AddSubnet(sourcePrefix, destPrefix netip.Prefix, rewriteTo string, portRanges []PortRange, disableIcmp bool) {
-	sl.mu.Lock()
-	defer sl.mu.Unlock()
-
-	key := ruleKey{
-		sourcePrefix: sourcePrefix.String(),
-		destPrefix:   destPrefix.String(),
-	}
-
-	sl.rules[key] = &SubnetRule{
-		SourcePrefix: sourcePrefix,
-		DestPrefix:   destPrefix,
-		DisableIcmp:  disableIcmp,
-		RewriteTo:    rewriteTo,
-		PortRanges:   portRanges,
-	}
-}
-
-// RemoveSubnet removes a subnet rule from the lookup table
-func (sl *SubnetLookup) RemoveSubnet(sourcePrefix, destPrefix netip.Prefix) {
-	sl.mu.Lock()
-	defer sl.mu.Unlock()
-
-	key := ruleKey{
-		sourcePrefix: sourcePrefix.String(),
-		destPrefix:   destPrefix.String(),
-	}
-
-	delete(sl.rules, key)
-}
-
-// Match checks if a source IP, destination IP, port, and protocol match any subnet rule
-// Returns the matched rule if ALL of these conditions are met:
-//   - The source IP is in the rule's source prefix
-//   - The destination IP is in the rule's destination prefix
-//   - The port is in an allowed range (or no port restrictions exist)
-//   - The protocol matches (or the port range allows both protocols)
-//
-// proto should be header.TCPProtocolNumber or header.UDPProtocolNumber
-// Returns nil if no rule matches
-func (sl *SubnetLookup) Match(srcIP, dstIP netip.Addr, port uint16, proto tcpip.TransportProtocolNumber) *SubnetRule {
-	sl.mu.RLock()
-	defer sl.mu.RUnlock()
-
-	// Iterate through all rules to find matching source and destination prefixes
-	// This is O(n) but necessary since we need to check prefix containment, not exact match
-	for _, rule := range sl.rules {
-		// Check if source and destination IPs match their respective prefixes
-		if !rule.SourcePrefix.Contains(srcIP) {
-			continue
-		}
-		if !rule.DestPrefix.Contains(dstIP) {
-			continue
-		}
-
-		if rule.DisableIcmp && (proto == header.ICMPv4ProtocolNumber || proto == header.ICMPv6ProtocolNumber) {
-		    // ICMP is disabled for this subnet
-			return nil
-		}
-
-		// Both IPs match - now check port restrictions
-		// If no port ranges specified, all ports are allowed
-		if len(rule.PortRanges) == 0 {
-			return rule
-		}
-
-		// Check if port and protocol are in any of the allowed ranges
-		for _, pr := range rule.PortRanges {
-			if port >= pr.Min && port <= pr.Max {
-				// Check protocol compatibility
-				if pr.Protocol == "" {
-					// Empty protocol means allow both TCP and UDP
-					return rule
-				}
-				// Check if the packet protocol matches the port range protocol
-				if (pr.Protocol == "tcp" && proto == header.TCPProtocolNumber) ||
-					(pr.Protocol == "udp" && proto == header.UDPProtocolNumber) {
-					return rule
-				}
-				// Port matches but protocol doesn't - continue checking other ranges
-			}
-		}
-	}
-
-	return nil
-}
-
 // connKey uniquely identifies a connection for NAT tracking
 type connKey struct {
 	srcIP   string
diff --git a/netstack2/subnet_lookup.go b/netstack2/subnet_lookup.go
new file mode 100644
index 0000000..fcfed63
--- /dev/null
+++ b/netstack2/subnet_lookup.go
@@ -0,0 +1,203 @@
+package netstack2
+
+import (
+	"net/netip"
+	"sync"
+
+	"github.com/gaissmai/bart"
+	"gvisor.dev/gvisor/pkg/tcpip"
+	"gvisor.dev/gvisor/pkg/tcpip/header"
+)
+
+// SubnetLookup provides fast IP subnet and port matching using BART (Binary Aggregated Range Tree)
+// This uses BART Table for O(log n) prefix matching with Supernets() for efficient lookups
+//
+// Architecture:
+// - Two-level BART structure for matching both source AND destination prefixes
+// - Level 1: Source prefix -> Level 2 (destination prefix -> rules)
+// - This reduces search space: only check destination prefixes for matching source prefixes
+type SubnetLookup struct {
+	mu sync.RWMutex
+	// Two-level BART structure:
+	// Level 1: Source prefix -> Level 2 (destination prefix -> rules)
+	// This allows us to first match source prefix, then only check destination prefixes
+	// for matching source prefixes, reducing the search space significantly
+	sourceTrie *bart.Table[*destTrie]
+}
+
+// destTrie is a BART for destination prefixes, containing the actual rules
+type destTrie struct {
+	trie  *bart.Table[[]*SubnetRule]
+	rules []*SubnetRule // All rules for this source prefix (for iteration if needed)
+}
+
+// NewSubnetLookup creates a new subnet lookup table using BART
+func NewSubnetLookup() *SubnetLookup {
+	return &SubnetLookup{
+		sourceTrie: &bart.Table[*destTrie]{},
+	}
+}
+
+// prefixEqual compares two prefixes after masking to handle host bits correctly.
+// For example, 10.0.0.5/24 and 10.0.0.0/24 are treated as equal.
+func prefixEqual(a, b netip.Prefix) bool {
+	return a.Masked() == b.Masked()
+}
+
+// AddSubnet adds a subnet rule with source and destination prefixes and optional port restrictions
+// If portRanges is nil or empty, all ports are allowed for this subnet
+// rewriteTo can be either an IP/CIDR (e.g., "192.168.1.1/32") or a domain name (e.g., "example.com")
+func (sl *SubnetLookup) AddSubnet(sourcePrefix, destPrefix netip.Prefix, rewriteTo string, portRanges []PortRange, disableIcmp bool) {
+	sl.mu.Lock()
+	defer sl.mu.Unlock()
+
+	rule := &SubnetRule{
+		SourcePrefix: sourcePrefix,
+		DestPrefix:   destPrefix,
+		DisableIcmp:  disableIcmp,
+		RewriteTo:    rewriteTo,
+		PortRanges:   portRanges,
+	}
+
+	// Canonicalize source prefix to handle host bits correctly
+	canonicalSourcePrefix := sourcePrefix.Masked()
+
+	// Get or create destination trie for this source prefix
+	destTriePtr, exists := sl.sourceTrie.Get(canonicalSourcePrefix)
+	if !exists {
+		// Create new destination trie for this source prefix
+		destTriePtr = &destTrie{
+			trie:  &bart.Table[[]*SubnetRule]{},
+			rules: make([]*SubnetRule, 0),
+		}
+		sl.sourceTrie.Insert(canonicalSourcePrefix, destTriePtr)
+	}
+
+	// Canonicalize destination prefix to handle host bits correctly
+	// BART masks prefixes internally, so we need to match that behavior in our bookkeeping
+	canonicalDestPrefix := destPrefix.Masked()
+
+	// Add rule to destination trie
+	// Original behavior: overwrite if same (sourcePrefix, destPrefix) exists
+	// Store as single-element slice to match original overwrite behavior
+	destTriePtr.trie.Insert(canonicalDestPrefix, []*SubnetRule{rule})
+
+	// Update destTriePtr.rules - remove old rule with same canonical prefix if exists, then add new one
+	// Use canonical comparison to handle cases like 10.0.0.5/24 vs 10.0.0.0/24
+	newRules := make([]*SubnetRule, 0, len(destTriePtr.rules)+1)
+	for _, r := range destTriePtr.rules {
+		if !prefixEqual(r.DestPrefix, canonicalDestPrefix) || !prefixEqual(r.SourcePrefix, canonicalSourcePrefix) {
+			newRules = append(newRules, r)
+		}
+	}
+	newRules = append(newRules, rule)
+	destTriePtr.rules = newRules
+}
+
+// RemoveSubnet removes a subnet rule from the lookup table
+func (sl *SubnetLookup) RemoveSubnet(sourcePrefix, destPrefix netip.Prefix) {
+	sl.mu.Lock()
+	defer sl.mu.Unlock()
+
+	// Canonicalize prefixes to handle host bits correctly
+	canonicalSourcePrefix := sourcePrefix.Masked()
+	canonicalDestPrefix := destPrefix.Masked()
+
+	destTriePtr, exists := sl.sourceTrie.Get(canonicalSourcePrefix)
+	if !exists {
+		return
+	}
+
+	// Remove the rule - original behavior: delete exact (sourcePrefix, destPrefix) combination
+	// BART masks prefixes internally, so Delete works with canonical form
+	destTriePtr.trie.Delete(canonicalDestPrefix)
+
+	// Also remove from destTriePtr.rules using canonical comparison
+	// This ensures we remove rules even if they were added with host bits set
+	newDestRules := make([]*SubnetRule, 0, len(destTriePtr.rules))
+	for _, r := range destTriePtr.rules {
+		if !prefixEqual(r.DestPrefix, canonicalDestPrefix) || !prefixEqual(r.SourcePrefix, canonicalSourcePrefix) {
+			newDestRules = append(newDestRules, r)
+		}
+	}
+	destTriePtr.rules = newDestRules
+
+	// Check if the trie is actually empty using BART's Size() method
+	// This is more efficient than iterating and ensures we clean up empty tries
+	// even if there were stale entries in the rules slice (which shouldn't happen
+	// with proper canonicalization, but this provides a definitive check)
+	if destTriePtr.trie.Size() == 0 {
+		sl.sourceTrie.Delete(canonicalSourcePrefix)
+	}
+}
+
+// Match checks if a source IP, destination IP, port, and protocol match any subnet rule
+// Returns the matched rule if ALL of these conditions are met:
+//   - The source IP is in the rule's source prefix
+//   - The destination IP is in the rule's destination prefix
+//   - The port is in an allowed range (or no port restrictions exist)
+//   - The protocol matches (or the port range allows both protocols)
+//
+// proto should be header.TCPProtocolNumber, header.UDPProtocolNumber, or header.ICMPv4ProtocolNumber
+// Returns nil if no rule matches
+// This uses BART's Supernets() for O(log n) prefix matching instead of O(n) iteration
+func (sl *SubnetLookup) Match(srcIP, dstIP netip.Addr, port uint16, proto tcpip.TransportProtocolNumber) *SubnetRule {
+	sl.mu.RLock()
+	defer sl.mu.RUnlock()
+
+	// Convert IP addresses to /32 (IPv4) or /128 (IPv6) prefixes
+	// Supernets() finds all prefixes that contain this IP (i.e., are supernets of /32 or /128)
+	srcPrefix := netip.PrefixFrom(srcIP, srcIP.BitLen())
+	dstPrefix := netip.PrefixFrom(dstIP, dstIP.BitLen())
+
+	// Step 1: Find all source prefixes that contain srcIP using BART's Supernets
+	// This is O(log n) instead of O(n) iteration
+	// Supernets returns all prefixes that are supernets (contain) the given prefix
+	for _, destTriePtr := range sl.sourceTrie.Supernets(srcPrefix) {
+		if destTriePtr == nil {
+			continue
+		}
+
+		// Step 2: Find all destination prefixes that contain dstIP
+		// This is also O(log n) for each matching source prefix
+		for _, rules := range destTriePtr.trie.Supernets(dstPrefix) {
+			if rules == nil {
+				continue
+			}
+
+			// Step 3: Check each rule for ICMP and port restrictions
+			for _, rule := range rules {
+				// Check if ICMP is disabled for this rule
+				if rule.DisableIcmp && (proto == header.ICMPv4ProtocolNumber || proto == header.ICMPv6ProtocolNumber) {
+					// ICMP is disabled for this subnet
+					return nil
+				}
+
+				// Check port restrictions
+				if len(rule.PortRanges) == 0 {
+					// No port restrictions, match!
+					return rule
+				}
+
+				// Check if port and protocol are in any of the allowed ranges
+				for _, pr := range rule.PortRanges {
+					if port >= pr.Min && port <= pr.Max {
+						// Check protocol compatibility
+						if pr.Protocol == "" {
+							// Empty protocol means allow both TCP and UDP
+							return rule
+						}
+						// Check if the packet protocol matches the port range protocol
+						if (pr.Protocol == "tcp" && proto == header.TCPProtocolNumber) ||
+							(pr.Protocol == "udp" && proto == header.UDPProtocolNumber) {
+							return rule
+						}
+						// Port matches but protocol doesn't - continue checking other ranges
+					}
+				}
+			}
+		}
+	}
+
+	return nil
+}