This document describes the construction of an onion routed packet that is used to route a payment from an origin node to a final node. The packet is routed through a number of intermediate nodes, called hops.
The routing schema is based on the Sphinx construction and is extended with a per-hop payload.
Intermediate nodes forwarding the message can verify the integrity of the packet and can learn which node they should forward the packet to. They cannot learn which other nodes, besides their predecessor or successor, are part of the packet's route; nor can they learn the length of the route or their position within it. The packet is obfuscated at each hop, to ensure that a network-level attacker cannot associate packets belonging to the same route (i.e. packets belonging to the same route do not share any correlating information). Notice that this does not preclude the possibility of packet association by an attacker via traffic analysis.
The route is constructed by the origin node, which knows the public keys of each intermediate node and of the final node. Knowing each node's public key allows the origin node to create a shared secret (using ECDH) for each intermediate node and for the final node. The shared secret is then used to generate a pseudo-random stream of bytes (which is used to obfuscate the packet) and a number of keys (which are used to encrypt the payload and compute the HMACs). The HMACs are then in turn used to ensure the integrity of the packet at each hop.
Each hop along the route only sees an ephemeral key for the origin node, in order to hide the sender's identity. The ephemeral key is blinded by each intermediate hop before forwarding to the next, making the onions unlinkable along the route.
This specification describes version 0 of the packet format and routing mechanism.
A node:
- upon receiving a higher version packet than it implements:
- MUST report a route failure to the origin node.
- MUST discard the packet.
- Conventions
- Key Generation
- Pseudo Random Byte Stream
- Packet Structure
- Accepting and Forwarding a Payment
- Shared Secret
- Blinding Ephemeral Keys
- Packet Construction
- Packet Forwarding
- Filler Generation
- Returning Errors
- Test Vector
- References
- Authors
There are a number of conventions adhered to throughout this document:
- HMAC: the integrity verification of the packet is based on Keyed-Hash
Message Authentication Code, as defined by the FIPS 198
Standard/RFC 2104, and using a
SHA256
hashing algorithm. - Elliptic curve: for all computations involving elliptic curves, the Bitcoin
curve is used, as specified in
secp256k1
- Pseudo-random stream:
ChaCha20
is used to generate a pseudo-random byte stream. For its generation, a fixed 96-bit null-nonce (0x000000000000000000000000
) is used, along with a key derived from a shared secret and with a0x00
-byte stream of the desired output size as the message. - The terms origin node and final node refer to the initial packet sender and the final packet recipient, respectively.
- The terms hop and node are sometimes used interchangeably, but a hop usually refers to an intermediate node in the route rather than an end node. origin node --> hop --> ... --> hop --> final node
- The term processing node refers to the specific node along the route that is currently processing the forwarded packet.
- The term peers refers only to hops that are direct neighbors (in the overlay network): more specifically, sending peers forward packets to receiving peers.
- Each hop in the route has a variable length
hop_payload
, or a fixed-size legacyhop_data
payload.- The legacy
hop_data
is identified by a single0x00
-byte prefix - The variable length
hop_payload
is prefixed with abigsize
encoding the length in bytes, excluding the prefix and the trailing HMAC.
- The legacy
A number of encryption and verification keys are derived from the shared secret:
- rho: used as key when generating the pseudo-random byte stream that is used to obfuscate the per-hop information
- mu: used during the HMAC generation
- um: used during error reporting
- pad: use to generate random filler bytes for the starting mix-header packet
The key generation function takes a key-type (rho=0x72686F
, mu=0x6d75
,
um=0x756d
, or pad=0x706164
) and a 32-byte secret as inputs and returns
a 32-byte key.
Keys are generated by computing an HMAC (with SHA256
as hashing algorithm)
using the appropriate key-type (i.e. rho, mu, um, or pad) as HMAC-key
and the 32-byte shared secret as the message. The resulting HMAC is then
returned as the key.
Notice that the key-type does not include a C-style 0x00
-termination-byte,
e.g. the length of the rho key-type is 3 bytes, not 4.
The pseudo-random byte stream is used to obfuscate the packet at each hop of the
path, so that each hop may only recover the address and HMAC of the next hop.
The pseudo-random byte stream is generated by encrypting (using ChaCha20
) a
0x00
-byte stream, of the required length, which is initialized with a key
derived from the shared secret and a 96-bit zero-nonce (0x000000000000000000000000
).
The use of a fixed nonce is safe, since the keys are never reused.
The packet consists of four sections:
- a
version
byte - a 33-byte compressed
secp256k1
public_key
, used during the shared secret generation - a 1300-byte
hop_payloads
consisting of multiple, variable length,hop_payload
payloads or up to 20 fixed sized legacyhop_data
payloads. - a 32-byte
hmac
, used to verify the packet's integrity
The network format of the packet consists of the individual sections serialized into one contiguous byte-stream and then transferred to the packet recipient. Due to the fixed size of the packet, it need not be prefixed by its length when transferred over a connection.
The overall structure of the packet is as follows:
- type:
onion_packet
- data:
- [
byte
:version
] - [
point
:public_key
] - [
1300*byte
:hop_payloads
] - [
32*byte
:hmac
]
- [
For this specification (version 0), version
has a constant value of 0x00
.
The hop_payloads
field is a structure that holds obfuscated routing information, and associated HMAC.
It is 1300 bytes long and has the following structure:
- type:
hop_payloads
- data:
- [
bigsize
:length
] - [
hop_payload_length
:hop_payload
] - [
32*byte
:hmac
] - ...
filler
- [
Where, the length
, hop_payload
(with contents dependent on length
), and hmac
are repeated for each hop;
and where, filler
consists of obfuscated, deterministically-generated padding, as detailed in Filler Generation.
Additionally, hop_payloads
is incrementally obfuscated at each hop.
Using the hop_payload
field, the origin node is able to specify the path and structure of the HTLCs forwarded at each hop.
As the hop_payload
is protected under the packet-wide HMAC, the information it contains is fully authenticated with each pair-wise relationship between the HTLC sender (origin node) and each hop in the path.
Using this end-to-end authentication, each hop is able to cross-check the HTLC
parameters with the hop_payload
's specified values and to ensure that the
sending peer hasn't forwarded an ill-crafted HTLC.
The length
field determines both the length and the format of the hop_payload
field; the following formats are defined:
- Legacy
hop_data
format, identified by a single0x00
byte for length. In this case thehop_payload_length
is defined to be 32 bytes. tlv_payload
format, identified by any length over1
. In this case thehop_payload_length
is equal to the numeric value oflength
.- A single
0x01
byte for length is reserved for future use to signal a different payload format. This is safe since no TLV value can ever be shorter than 2 bytes. In this case thehop_payload_length
MUST be defined in the future specification making use of thislength
.
The hop_data
format is identified by a single 0x00
-byte length, for backward compatibility.
Its payload is defined as:
- type:
hop_data
(forrealm
0) - data:
- [
short_channel_id
:short_channel_id
] - [
u64
:amt_to_forward
] - [
u32
:outgoing_cltv_value
] - [
12*byte
:padding
]
- [
Field descriptions:
-
short_channel_id
: The ID of the outgoing channel used to route the message; the receiving peer should operate the other end of this channel. -
amt_to_forward
: The amount, in millisatoshis, to forward to the next receiving peer specified within the routing information.For non-final nodes, this value amount MUST include the origin node's computed fee for the receiving peer. When processing an incoming Sphinx packet and the HTLC message that it is encapsulated within, if the following inequality doesn't hold, then the HTLC should be rejected as it would indicate that a prior hop has deviated from the specified parameters:
incoming_htlc_amt - fee >= amt_to_forward
Where
fee
is calculated according to the receiving peer's advertised fee schema (as described in BOLT #7).For the final node, this value MUST be exactly equal to the incoming htlc amount, otherwise the HTLC should be rejected.
-
outgoing_cltv_value
: The CLTV value that the outgoing HTLC carrying the packet should have.cltv_expiry - cltv_expiry_delta >= outgoing_cltv_value
Inclusion of this field allows a hop to both authenticate the information specified by the origin node, and the parameters of the HTLC forwarded, and ensure the origin node is using the current
cltv_expiry_delta
value. If there is no next hop,cltv_expiry_delta
is 0. If the values don't correspond, then the HTLC should be failed and rejected, as this indicates that either a forwarding node has tampered with the intended HTLC values or that the origin node has an obsoletecltv_expiry_delta
value. The hop MUST be consistent in responding to an unexpectedoutgoing_cltv_value
, whether it is the final node or not, to avoid leaking its position in the route. -
padding
: This field is for future use and also for ensuring that future non-0-realm
hop_data
s won't change the overallhop_payloads
size.
When forwarding HTLCs, nodes MUST construct the outgoing HTLC as specified
within hop_data
above; otherwise, deviation from the specified HTLC
parameters may lead to extraneous routing failure.
This is a more flexible format, which avoids the redundant short_channel_id
field for the final node.
It is formatted according to the Type-Length-Value format defined in BOLT #1.
tlv_stream
:tlv_payload
- types:
- type: 2 (
amt_to_forward
) - data:
- [
tu64
:amt_to_forward
]
- [
- type: 4 (
outgoing_cltv_value
) - data:
- [
tu32
:outgoing_cltv_value
]
- [
- type: 6 (
short_channel_id
) - data:
- [
short_channel_id
:short_channel_id
]
- [
- type: 8 (
payment_data
) - data:
- [
32*byte
:payment_secret
] - [
tu64
:total_msat
]
- [
- type: 16 (
payment_metadata
) - data:
- [
...*byte
:payment_metadata
]
- [
- type: 2 (
The writer:
- Unless
node_announcement
,init
message or the BOLT #11 offers featurevar_onion_optin
:- MUST use the legacy payload format instead.
- For every node:
- MUST include
amt_to_forward
andoutgoing_cltv_value
.
- MUST include
- For every non-final node:
- MUST include
short_channel_id
- MUST NOT include
payment_data
- MUST include
- For the final node:
- MUST NOT include
short_channel_id
- if the recipient provided
payment_secret
:- MUST include
payment_data
- MUST set
payment_secret
to the one provided - MUST set
total_msat
to the total amount it will send
- MUST include
- if the recipient provided
payment_metadata
:- MUST include
payment_metadata
with every HTLC - MUST not apply any limits to the size of payment_metadata except the limits implied by the fixed onion size
- MUST include
- MUST NOT include
The reader:
- MUST return an error if
amt_to_forward
oroutgoing_cltv_value
are not present. - if it is the final node:
- MUST treat
total_msat
as if it were equal toamt_to_forward
if it is not present.
- MUST treat
The requirements for the contents of these fields are specified above and below.
An HTLC may be part of a larger "multi-part" payment: such
"base" atomic multipath payments will use the same payment_hash
for
all paths.
Note that amt_to_forward
is the amount for this HTLC only: a
total_msat
field containing a greater value is a promise by the
ultimate sender that the rest of the payment will follow in succeeding
HTLCs; we call these outstanding HTLCs which have the same preimage,
an "HTLC set".
payment_metadata
is to be included in every payment part, so that
invalid payment details can be detected as early as possible.
The writer:
- if the invoice offers the
basic_mpp
feature:- MAY send more than one HTLC to pay the invoice.
- MUST use the same
payment_hash
on all HTLCs in the set. - SHOULD send all payments at approximately the same time.
- SHOULD try to use diverse paths to the recipient for each HTLC.
- SHOULD retry and/or re-divide HTLCs which fail.
- if the invoice specifies an
amount
:- MUST set
total_msat
to at least thatamount
, and less than or equal to twiceamount
.
- MUST set
- otherwise:
- MUST set
total_msat
to the amount it wishes to pay.
- MUST set
- MUST ensure that the total
amount_msat
of the HTLC set which arrives at the payee is equal tototal_msat
. - MUST NOT send another HTLC if the total
amount_msat
of the HTLC set is already greater or equal tototal_msat
. - MUST include
payment_secret
.
- otherwise:
- MUST set
total_msat
equal toamt_to_forward
.
- MUST set
The final node:
- MUST fail the HTLC if dictated by Requirements under Failure Messages
- Note: "amount paid" specified there is the
total_msat
field.
- Note: "amount paid" specified there is the
- if it does not support
basic_mpp
:- MUST fail the HTLC if
total_msat
is not exactly equal toamt_to_forward
.
- MUST fail the HTLC if
- otherwise, if it supports
basic_mpp
:- MUST add it to the HTLC set corresponding to that
payment_hash
. - SHOULD fail the entire HTLC set if
total_msat
is not the same for all HTLCs in the set. - if the total
amount_msat
of this HTLC set equalstotal_msat
:- SHOULD fulfill all HTLCs in the HTLC set
- otherwise, if the total
amount_msat
of this HTLC set is less thantotal_msat
:- MUST NOT fulfill any HTLCs in the HTLC set
- MUST fail all HTLCs in the HTLC set after some reasonable timeout.
- SHOULD wait for at least 60 seconds after the initial HTLC.
- SHOULD use
mpp_timeout
for the failure message.
- MUST require
payment_secret
for all HTLCs in the set.
- if it fulfills any HTLCs in the HTLC set:
- MUST fulfill the entire HTLC set.
- MUST add it to the HTLC set corresponding to that
If basic_mpp
is present it causes a delay to allow other partial
payments to combine. The total amount must be sufficient for the
desired payment, just as it must be for single payments. But this must
be reasonably bounded to avoid a denial-of-service.
Because invoices do not necessarily specify an amount, and because payers can add noise to the final amount, the total amount must be sent explicitly. The requirements allow exceeding this slightly, as it simplifies adding noise to the amount when splitting, as well as scenarios in which the senders are genuinely independent (friends splitting a bill, for example).
The restriction on sending an HTLC once the set is over the agreed total prevents the preimage being released before all the partial payments have arrived: that would allow any intermediate node to immediately claim any outstanding partial payments.
An implementation may choose not to fulfill an HTLC set which otherwise meets the amount criterion (eg. some other failure, or invoice timeout), however if it were to fulfill only some of them, intermediary nodes could simply claim the remaining ones.
Once a node has decoded the payload it either accepts the payment locally, or forwards it to the peer indicated as the next hop in the payload.
A node MAY forward an HTLC along an outgoing channel other than the one
specified by short_channel_id
, so long as the receiver has the same node
public key intended by short_channel_id
. Thus, if short_channel_id
connects
nodes A and B, the HTLC can be forwarded across any channel connecting A and B.
Failure to adhere will result in the receiver being unable to decrypt the next
hop in the onion packet.
In the event that two peers have multiple channels, the downstream node will be able to decrypt the next hop payload regardless of which channel the packet is sent across.
Nodes implementing non-strict forwarding are able to make real-time assessments of channel bandwidths with a particular peer, and use the channel that is locally-optimal.
For example, if the channel specified by short_channel_id
connecting A and B
does not have enough bandwidth at forwarding time, then A is able use a
different channel that does. This can reduce payment latency by preventing the
HTLC from failing due to bandwidth constraints across short_channel_id
, only
to have the sender attempt the same route differing only in the channel between
A and B.
Non-strict forwarding allows nodes to make use of private channels connecting them to the receiving node, even if the channel is not known in the public channel graph.
Implementations using non-strict forwarding should consider applying the same fee schedule to all channels with the same peer, as senders are likely to select the channel which results in the lowest overall cost. Having distinct policies may result in the forwarding node accepting fees based on the most optimal fee schedule for the sender, even though they are providing aggregate bandwidth across all channels with the same peer.
Alternatively, implementations may choose to apply non-strict forwarding only to like-policy channels to ensure their expected fee revenue does not deviate by using an alternate channel.
When building the route, the origin node MUST use a payload for the final node with the following values:
payment_secret
: set to the payment secret specified by the recipient (e.g.payment_secret
from a BOLT #11 payment invoice)outgoing_cltv_value
: set to the final expiry specified by the recipient (e.g.min_final_cltv_expiry
from a BOLT #11 payment invoice)amt_to_forward
: set to the final amount specified by the recipient (e.g.amount
from a BOLT #11 payment invoice)
This allows the final node to check these values and return errors if needed, but it also eliminates the possibility of probing attacks by the second-to-last node. Such attacks could, otherwise, attempt to discover if the receiving peer is the last one by re-sending HTLCs with different amounts/expiries. The final node will extract its onion payload from the HTLC it has received and compare its values against those of the HTLC. See the Returning Errors section below for more details.
If not for the above, since it need not forward payments, the final node could simply discard its payload.
The origin node establishes a shared secret with each hop along the route using
Elliptic-curve Diffie-Hellman between the sender's ephemeral key at that hop and
the hop's node ID key. The resulting curve point is serialized to the
compressed format and hashed using SHA256
. The hash output is used
as the 32-byte shared secret.
Elliptic-curve Diffie-Hellman (ECDH) is an operation on an EC private key and
an EC public key that outputs a curve point. For this protocol, the ECDH
variant implemented in libsecp256k1
is used, which is defined over the
secp256k1
elliptic curve. During packet construction, the sender uses the
ephemeral private key and the hop's public key as inputs to ECDH, whereas
during packet forwarding, the hop uses the ephemeral public key and its own
node ID private key. Because of the properties of ECDH, they will both derive
the same value.
In order to ensure multiple hops along the route cannot be linked by the ephemeral public keys they see, the key is blinded at each hop. The blinding is done in a deterministic way that allows the sender to compute the corresponding blinded private keys during packet construction.
The blinding of an EC public key is a single scalar multiplication of the EC point representing the public key with a 32-byte blinding factor. Due to the commutative property of scalar multiplication, the blinded private key is the multiplicative product of the input's corresponding private key with the same blinding factor.
The blinding factor itself is computed as a function of the ephemeral public key
and the 32-byte shared secret. Concretely, it is the SHA256
hash value of the
concatenation of the public key serialized in its compressed format and the
shared secret.
In the following example, it's assumed that a sending node (origin node),
n_0
, wants to route a packet to a receiving node (final node), n_r
.
First, the sender computes a route {n_0, n_1, ..., n_{r-1}, n_r}
, where n_0
is the sender itself and n_r
is the final recipient. All nodes n_i
and
n_{i+1}
MUST be peers in the overlay network route. The sender then gathers the
public keys for n_1
to n_r
and generates a random 32-byte sessionkey
.
Optionally, the sender may pass in associated data, i.e. data that the
packet commits to but that is not included in the packet itself. Associated
data will be included in the HMACs and must match the associated data provided
during integrity verification at each hop.
To construct the onion, the sender initializes the ephemeral private key for the
first hop ek_1
to the sessionkey
and derives from it the corresponding
ephemeral public key epk_1
by multiplying with the secp256k1
base point. For
each of the k
hops along the route, the sender then iteratively computes the
shared secret ss_k
and ephemeral key for the next hop ek_{k+1}
as follows:
- The sender executes ECDH with the hop's public key and the ephemeral private
key to obtain a curve point, which is hashed using
SHA256
to produce the shared secretss_k
. - The blinding factor is the
SHA256
hash of the concatenation between the ephemeral public keyepk_k
and the shared secretss_k
. - The ephemeral private key for the next hop
ek_{k+1}
is computed by multiplying the current ephemeral private keyek_k
by the blinding factor. - The ephemeral public key for the next hop
epk_{k+1}
is derived from the ephemeral private keyek_{k+1}
by multiplying with the base point.
Once the sender has all the required information above, it can construct the
packet. Constructing a packet routed over r
hops requires r
32-byte
ephemeral public keys, r
32-byte shared secrets, r
32-byte blinding factors,
and r
variable length hop_payload
payloads.
The construction returns a single 1366-byte packet along with the first receiving peer's address.
The packet construction is performed in the reverse order of the route, i.e. the last hop's operations are applied first.
The packet is initialized with 1300 random bytes derived from a CSPRNG
(ChaCha20). The pad key referenced above is used to extract additional random
bytes from a ChaCha20 stream, using it as a CSPRNG for this purpose. Once the
paddingKey
has been obtained, ChaCha20 is used with an all zero nonce, to
generate 1300 random bytes. Those random bytes are then used as the starting
state of the mix-header to be created.
A filler is generated (see Filler Generation) using the shared secret.
For each hop in the route, in reverse order, the sender applies the following operations:
- The rho-key and mu-key are generated using the hop's shared secret.
shift_size
is defined as the length of thehop_payload
plus the bigsize encoding of the length and the length of that HMAC. Thus if the payload length isl
then theshift_size
is1 + l + 32
forl < 253
, otherwise3 + l + 32
due to the bigsize encoding ofl
.- The
hop_payload
field is right-shifted byshift_size
bytes, discarding the lastshift_size
bytes that exceed its 1300-byte size. - The bigsize-serialized length, serialized
hop_payload
andhmac
are copied into the followingshift_size
bytes. - The rho-key is used to generate 1300 bytes of pseudo-random byte stream
which is then applied, with
XOR
, to thehop_payloads
field. - If this is the last hop, i.e. the first iteration, then the tail of the
hop_payloads
field is overwritten with the routing informationfiller
. - The next HMAC is computed (with the mu-key as HMAC-key) over the
concatenated
hop_payloads
and associated data.
The resulting final HMAC value is the HMAC that will be used by the first receiving peer in the route.
The packet generation returns a serialized packet that contains the version
byte, the ephemeral pubkey for the first hop, the HMAC for the first hop, and
the obfuscated hop_payloads
.
The following Go code is an example implementation of the packet construction:
func NewOnionPacket(paymentPath []*btcec.PublicKey, sessionKey *btcec.PrivateKey,
hopsData []HopData, assocData []byte) (*OnionPacket, error) {
numHops := len(paymentPath)
hopSharedSecrets := make([][sha256.Size]byte, numHops)
// Initialize ephemeral key for the first hop to the session key.
var ephemeralKey big.Int
ephemeralKey.Set(sessionKey.D)
for i := 0; i < numHops; i++ {
// Perform ECDH and hash the result.
ecdhResult := scalarMult(paymentPath[i], ephemeralKey)
hopSharedSecrets[i] = sha256.Sum256(ecdhResult.SerializeCompressed())
// Derive ephemeral public key from private key.
ephemeralPrivKey := btcec.PrivKeyFromBytes(btcec.S256(), ephemeralKey.Bytes())
ephemeralPubKey := ephemeralPrivKey.PubKey()
// Compute blinding factor.
sha := sha256.New()
sha.Write(ephemeralPubKey.SerializeCompressed())
sha.Write(hopSharedSecrets[i])
var blindingFactor big.Int
blindingFactor.SetBytes(sha.Sum(nil))
// Blind ephemeral key for next hop.
ephemeralKey.Mul(&ephemeralKey, &blindingFactor)
ephemeralKey.Mod(&ephemeralKey, btcec.S256().Params().N)
}
// Generate the padding, called "filler strings" in the paper.
filler := generateHeaderPadding("rho", numHops, hopDataSize, hopSharedSecrets)
// Allocate and initialize fields to zero-filled slices
var mixHeader [routingInfoSize]byte
var nextHmac [hmacSize]byte
// Our starting packet needs to be filled out with random bytes, we
// generate some determinstically using the session private key.
paddingKey := generateKey("pad", sessionKey.Serialize()
paddingBytes := generateCipherStream(paddingKey, routingInfoSize)
copy(mixHeader[:], paddingBytes)
// Compute the routing information for each hop along with a
// MAC of the routing information using the shared key for that hop.
for i := numHops - 1; i >= 0; i-- {
rhoKey := generateKey("rho", hopSharedSecrets[i])
muKey := generateKey("mu", hopSharedSecrets[i])
hopsData[i].HMAC = nextHmac
// Shift and obfuscate routing information
streamBytes := generateCipherStream(rhoKey, numStreamBytes)
rightShift(mixHeader[:], hopDataSize)
buf := &bytes.Buffer{}
hopsData[i].Encode(buf)
copy(mixHeader[:], buf.Bytes())
xor(mixHeader[:], mixHeader[:], streamBytes[:routingInfoSize])
// These need to be overwritten, so every node generates a correct padding
if i == numHops-1 {
copy(mixHeader[len(mixHeader)-len(filler):], filler)
}
packet := append(mixHeader[:], assocData...)
nextHmac = calcMac(muKey, packet)
}
packet := &OnionPacket{
Version: 0x00,
EphemeralKey: sessionKey.PubKey(),
RoutingInfo: mixHeader,
HeaderMAC: nextHmac,
}
return packet, nil
}
This specification is limited to version
0
packets; the structure
of future versions may change.
Upon receiving a packet, a processing node compares the version byte of the packet with its own supported versions and aborts the connection if the packet specifies a version number that it doesn't support. For packets with supported version numbers, the processing node first parses the packet into its individual fields.
Next, the processing node computes the shared secret using the private key corresponding to its own public key and the ephemeral key from the packet, as described in Shared Secret.
The above requirements prevent any hop along the route from retrying a payment
multiple times, in an attempt to track a payment's progress via traffic
analysis. Note that disabling such probing could be accomplished using a log of
previous shared secrets or HMACs, which could be forgotten once the HTLC would
not be accepted anyway (i.e. after outgoing_cltv_value
has passed). Such a log
may use a probabilistic data structure, but it MUST rate-limit commitments as
necessary, in order to constrain the worst-case storage requirements or false
positives of this log.
Next, the processing node uses the shared secret to compute a mu-key, which it
in turn uses to compute the HMAC of the hop_payloads
. The resulting HMAC is then
compared against the packet's HMAC.
Comparison of the computed HMAC and the packet's HMAC MUST be time-constant to avoid information leaks.
At this point, the processing node can generate a rho-key.
The routing information is then deobfuscated, and the information about the
next hop is extracted.
To do so, the processing node copies the hop_payloads
field, appends 1300 0x00
-bytes,
generates 2*1300
pseudo-random bytes (using the rho-key), and applies the result, using XOR
, to the copy of the hop_payloads
.
The first few bytes correspond to the bigsize-encoded length l
of the hop_payload
, followed by l
bytes of the resulting routing information become the hop_payload
, and the 32 byte HMAC.
The next 1300 bytes are the hop_payloads
for the outgoing packet.
A special hmac
value of 32 0x00
-bytes indicates that the currently processing hop is the intended recipient and that the packet should not be forwarded.
If the HMAC does not indicate route termination, and if the next hop is a peer of the
processing node; then the new packet is assembled. Packet assembly is accomplished
by blinding the ephemeral key with the processing node's public key, along with the
shared secret, and by serializing the hop_payloads
.
The resulting packet is then forwarded to the addressed peer.
The processing node:
- if the ephemeral public key is NOT on the
secp256k1
curve:- MUST abort processing the packet.
- MUST report a route failure to the origin node.
- if the packet has previously been forwarded or locally redeemed, i.e. the
packet contains duplicate routing information to a previously received packet:
- if preimage is known:
- MAY immediately redeem the HTLC using the preimage.
- otherwise:
- MUST abort processing and report a route failure.
- if preimage is known:
- if the computed HMAC and the packet's HMAC differ:
- MUST abort processing.
- MUST report a route failure.
- if the
realm
is unknown:- MUST drop the packet.
- MUST signal a route failure.
- MUST address the packet to another peer that is its direct neighbor.
- if the processing node does not have a peer with the matching address:
- MUST drop the packet.
- MUST signal a route failure.
Upon receiving a packet, the processing node extracts the information destined for it from the route information and the per-hop payload. The extraction is done by deobfuscating and left-shifting the field. This would make the field shorter at each hop, allowing an attacker to deduce the route length. For this reason, the field is pre-padded before forwarding. Since the padding is part of the HMAC, the origin node will have to pre-generate an identical padding (to that which each hop will generate) in order to compute the HMACs correctly for each hop. The filler is also used to pad the field-length, in the case that the selected route is shorter than 1300 bytes.
Before deobfuscating the hop_payloads
, the processing node pads it with 1300
0x00
-bytes, such that the total length is 2*1300
.
It then generates the pseudo-random byte stream, of matching length, and applies
it with XOR
to the hop_payloads
.
This deobfuscates the information destined for it, while simultaneously
obfuscating the added 0x00
-bytes at the end.
In order to compute the correct HMAC, the origin node has to pre-generate the
hop_payloads
for each hop, including the incrementally obfuscated padding added
by each hop. This incrementally obfuscated padding is referred to as the
filler
.
The following example code shows how the filler is generated in Go:
func generateFiller(key string, numHops int, hopSize int, sharedSecrets [][sharedSecretSize]byte) []byte {
fillerSize := uint((numMaxHops + 1) * hopSize)
filler := make([]byte, fillerSize)
// The last hop does not obfuscate, it's not forwarding anymore.
for i := 0; i < numHops-1; i++ {
// Left-shift the field
copy(filler[:], filler[hopSize:])
// Zero-fill the last hop
copy(filler[len(filler)-hopSize:], bytes.Repeat([]byte{0x00}, hopSize))
// Generate pseudo-random byte stream
streamKey := generateKey(key, sharedSecrets[i])
streamBytes := generateCipherStream(streamKey, fillerSize)
// Obfuscate
xor(filler, filler, streamBytes)
}
// Cut filler down to the correct length (numHops+1)*hopSize
// bytes will be prepended by the packet generation.
return filler[(numMaxHops-numHops+2)*hopSize:]
}
Note that this example implementation is for demonstration purposes only; the
filler
can be generated much more efficiently.
The last hop need not obfuscate the filler
, since it won't forward the packet
any further and thus need not extract an HMAC either.
The onion routing protocol includes a simple mechanism for returning encrypted error messages to the origin node. The returned error messages may be failures reported by any hop, including the final node. The format of the forward packet is not usable for the return path, since no hop besides the origin has access to the information required for its generation. Note that these error messages are not reliable, as they are not placed on-chain due to the possibility of hop failure.
Intermediate hops store the shared secret from the forward path and reuse it to obfuscate any corresponding return packet during each hop. In addition, each node locally stores data regarding its own sending peer in the route, so it knows where to return-forward any eventual return packets. The node generating the error message (erring node) builds a return packet consisting of the following fields:
- data:
- [
32*byte
:hmac
] - [
u16
:failure_len
] - [
failure_len*byte
:failuremsg
] - [
u16
:pad_len
] - [
pad_len*byte
:pad
]
- [
Where hmac
is an HMAC authenticating the remainder of the packet, with a key
generated using the above process, with key type um
, failuremsg
as defined
below, and pad
as the extra bytes used to conceal length.
The erring node then generates a new key, using the key type ammag
.
This key is then used to generate a pseudo-random stream, which is in turn
applied to the packet using XOR
.
The obfuscation step is repeated by every hop along the return path.
Upon receiving a return packet, each hop generates its ammag
, generates the
pseudo-random byte stream, and applies the result to the return packet before
return-forwarding it.
The origin node is able to detect that it's the intended final recipient of the
return message, because of course, it was the originator of the corresponding
forward packet.
When an origin node receives an error message matching a transfer it initiated
(i.e. it cannot return-forward the error any further) it generates the ammag
and um
keys for each hop in the route.
It then iteratively decrypts the error message, using each hop's ammag
key, and computes the HMAC, using each hop's um
key.
The origin node can detect the sender of the error message by matching the
hmac
field with the computed HMAC.
The association between the forward and return packets is handled outside of this onion routing protocol, e.g. via association with an HTLC in a payment channel.
The erring node:
- SHOULD set
pad
such that thefailure_len
pluspad_len
is equal to 256.- Note: this value is 118 bytes longer than the longest currently-defined message.
The origin node:
- once the return message has been decrypted:
- SHOULD store a copy of the message.
- SHOULD continue decrypting, until the loop has been repeated 20 times.
- SHOULD use constant
ammag
andum
keys to obfuscate the route length.
The failure message encapsulated in failuremsg
has an identical format as
a normal message: a 2-byte type failure_code
followed by data applicable
to that type. Below is a list of the currently supported failure_code
values, followed by their use case requirements.
Notice that the failure_code
s are not of the same type as other message types,
defined in other BOLTs, as they are not sent directly on the transport layer
but are instead wrapped inside return packets.
The numeric values for the failure_code
may therefore reuse values, that are
also assigned to other message types, without any danger of causing collisions.
The top byte of failure_code
can be read as a set of flags:
- 0x8000 (BADONION): unparsable onion encrypted by sending peer
- 0x4000 (PERM): permanent failure (otherwise transient)
- 0x2000 (NODE): node failure (otherwise channel)
- 0x1000 (UPDATE): new channel update enclosed
Please note that the channel_update
field is mandatory in messages whose
failure_code
includes the UPDATE
flag.
The following failure_code
s are defined:
- type: PERM|1 (
invalid_realm
)
The realm
byte was not understood by the processing node.
- type: NODE|2 (
temporary_node_failure
)
General temporary failure of the processing node.
- type: PERM|NODE|2 (
permanent_node_failure
)
General permanent failure of the processing node.
- type: PERM|NODE|3 (
required_node_feature_missing
)
The processing node has a required feature which was not in this onion.
- type: BADONION|PERM|4 (
invalid_onion_version
) - data:
- [
sha256
:sha256_of_onion
]
- [
The version
byte was not understood by the processing node.
- type: BADONION|PERM|5 (
invalid_onion_hmac
) - data:
- [
sha256
:sha256_of_onion
]
- [
The HMAC of the onion was incorrect when it reached the processing node.
- type: BADONION|PERM|6 (
invalid_onion_key
) - data:
- [
sha256
:sha256_of_onion
]
- [
The ephemeral key was unparsable by the processing node.
- type: UPDATE|7 (
temporary_channel_failure
) - data:
- [
u16
:len
] - [
len*byte
:channel_update
]
- [
The channel from the processing node was unable to handle this HTLC, but may be able to handle it, or others, later.
- type: PERM|8 (
permanent_channel_failure
)
The channel from the processing node is unable to handle any HTLCs.
- type: PERM|9 (
required_channel_feature_missing
)
The channel from the processing node requires features not present in the onion.
- type: PERM|10 (
unknown_next_peer
)
The onion specified a short_channel_id
which doesn't match any
leading from the processing node.
- type: UPDATE|11 (
amount_below_minimum
) - data:
- [
u64
:htlc_msat
] - [
u16
:len
] - [
len*byte
:channel_update
]
- [
The HTLC amount was below the htlc_minimum_msat
of the channel from
the processing node.
- type: UPDATE|12 (
fee_insufficient
) - data:
- [
u64
:htlc_msat
] - [
u16
:len
] - [
len*byte
:channel_update
]
- [
The fee amount was below that required by the channel from the processing node.
- type: UPDATE|13 (
incorrect_cltv_expiry
) - data:
- [
u32
:cltv_expiry
] - [
u16
:len
] - [
len*byte
:channel_update
]
- [
The cltv_expiry
does not comply with the cltv_expiry_delta
required by
the channel from the processing node: it does not satisfy the following
requirement:
cltv_expiry - cltv_expiry_delta >= outgoing_cltv_value
- type: UPDATE|14 (
expiry_too_soon
) - data:
- [
u16
:len
] - [
len*byte
:channel_update
]
- [
The CLTV expiry is too close to the current block height for safe handling by the processing node.
- type: PERM|15 (
incorrect_or_unknown_payment_details
) - data:
- [
u64
:htlc_msat
] - [
u32
:height
]
- [
The payment_hash
is unknown to the final node, the payment_secret
doesn't
match the payment_hash
, the amount for that payment_hash
is incorrect,
the CLTV expiry of the htlc is too close to the current block height for safe
handling or payment_metadata
isn't present while it should be.
The htlc_msat
parameter is superfluous, but left in for backwards
compatibility. The value of htlc_msat
always matches the amount specified in
the final hop onion payload. It therefore does not have any informative value to
the sender. A penultimate hop sending a different amount or expiry for the htlc
is handled through final_incorrect_cltv_expiry
and
final_incorrect_htlc_amount
.
The height
parameter is set by the final node to the best known block height
at the time of receiving the htlc. This can be used by the sender to distinguish
between sending a payment with the wrong final CLTV expiry and an intermediate
hop delaying the payment so that the receiver's invoice CLTV delta requirement
is no longer met.
Note: Originally PERM|16 (incorrect_payment_amount
) and 17
(final_expiry_too_soon
) were used to differentiate incorrect htlc parameters
from unknown payment hash. Sadly, sending this response allows for probing
attacks whereby a node which receives an HTLC for forwarding can check guesses
as to its final destination by sending payments with the same hash but much
lower values or expiry heights to potential destinations and check the response.
Care must be taken by implementations to differentiate the previously
non-permanent case for final_expiry_too_soon
(17) from the other, permanent
failures now represented by incorrect_or_unknown_payment_details
(PERM|15).
- type: 18 (
final_incorrect_cltv_expiry
) - data:
- [
u32
:cltv_expiry
]
- [
The CLTV expiry in the HTLC doesn't match the value in the onion.
- type: 19 (
final_incorrect_htlc_amount
) - data:
- [
u64
:incoming_htlc_amt
]
- [
The amount in the HTLC doesn't match the value in the onion.
- type: UPDATE|20 (
channel_disabled
) - data:
- [
u16
:flags
] - [
u16
:len
] - [
len*byte
:channel_update
]
- [
The channel from the processing node has been disabled.
- type: 21 (
expiry_too_far
)
The CLTV expiry in the HTLC is too far in the future.
- type: PERM|22 (
invalid_onion_payload
) - data:
- [
bigsize
:type
] - [
u16
:offset
]
- [
The decrypted onion per-hop payload was not understood by the processing node
or is incomplete. If the failure can be narrowed down to a specific tlv type in
the payload, the erring node may include that type
and its byte offset
in
the decrypted byte stream.
- type: 23 (
mpp_timeout
)
The complete amount of the multi-part payment was not received within a reasonable time.
An erring node:
- MUST select one of the above error codes when creating an error message.
- MUST include the appropriate data for that particular error type.
- if there is more than one error:
- SHOULD select the first error it encounters from the list above.
Any erring node MAY:
- if the
realm
byte is unknown:- return an
invalid_realm
error.
- return an
- if the per-hop payload in the onion is invalid (e.g. it is not a valid tlv stream)
or is missing required information (e.g. the amount was not specified):
- return an
invalid_onion_payload
error.
- return an
- if an otherwise unspecified transient error occurs for the entire node:
- return a
temporary_node_failure
error.
- return a
- if an otherwise unspecified permanent error occurs for the entire node:
- return a
permanent_node_failure
error.
- return a
- if a node has requirements advertised in its
node_announcement
features
, which were NOT included in the onion:- return a
required_node_feature_missing
error.
- return a
A forwarding node MAY, but a final node MUST NOT:
- if the onion
version
byte is unknown:- return an
invalid_onion_version
error.
- return an
- if the onion HMAC is incorrect:
- return an
invalid_onion_hmac
error.
- return an
- if the ephemeral key in the onion is unparsable:
- return an
invalid_onion_key
error.
- return an
- if during forwarding to its receiving peer, an otherwise unspecified,
transient error occurs in the outgoing channel (e.g. channel capacity reached,
too many in-flight HTLCs, etc.):
- return a
temporary_channel_failure
error.
- return a
- if an otherwise unspecified, permanent error occurs during forwarding to its
receiving peer (e.g. channel recently closed):
- return a
permanent_channel_failure
error.
- return a
- if the outgoing channel has requirements advertised in its
channel_announcement
'sfeatures
, which were NOT included in the onion:- return a
required_channel_feature_missing
error.
- return a
- if the receiving peer specified by the onion is NOT known:
- return an
unknown_next_peer
error.
- return an
- if the HTLC amount is less than the currently specified minimum amount:
- report the amount of the outgoing HTLC and the current channel setting for the outgoing channel.
- return an
amount_below_minimum
error.
- if the HTLC does NOT pay a sufficient fee:
- report the amount of the incoming HTLC and the current channel setting for the outgoing channel.
- return a
fee_insufficient
error.
- if the incoming
cltv_expiry
minus theoutgoing_cltv_value
is below thecltv_expiry_delta
for the outgoing channel:- report the
cltv_expiry
of the outgoing HTLC and the current channel setting for the outgoing channel. - return an
incorrect_cltv_expiry
error.
- report the
- if the
cltv_expiry
is unreasonably near the present:- report the current channel setting for the outgoing channel.
- return an
expiry_too_soon
error.
- if the
cltv_expiry
is unreasonably far in the future:- return an
expiry_too_far
error.
- return an
- if the channel is disabled:
- report the current channel setting for the outgoing channel.
- return a
channel_disabled
error.
An intermediate hop MUST NOT, but the final node:
- if the payment hash has already been paid:
- MAY treat the payment hash as unknown.
- MAY succeed in accepting the HTLC.
- if the
payment_secret
doesn't match the expected value for thatpayment_hash
, or thepayment_secret
is required and is not present:- MUST fail the HTLC.
- MUST return an
incorrect_or_unknown_payment_details
error.
- if the amount paid is less than the amount expected:
- MUST fail the HTLC.
- MUST return an
incorrect_or_unknown_payment_details
error.
- if the payment hash is unknown:
- MUST fail the HTLC.
- MUST return an
incorrect_or_unknown_payment_details
error.
- if the amount paid is more than twice the amount expected:
- SHOULD fail the HTLC.
- SHOULD return an
incorrect_or_unknown_payment_details
error.- Note: this allows the origin node to reduce information leakage by altering the amount while not allowing for accidental gross overpayment.
- if the
cltv_expiry
value is unreasonably near the present:- MUST fail the HTLC.
- MUST return an
incorrect_or_unknown_payment_details
error.
- if the
outgoing_cltv_value
does NOT correspond with thecltv_expiry
from the final node's HTLC:- MUST return
final_incorrect_cltv_expiry
error.
- MUST return
- if the
amt_to_forward
does NOT correspond with theincoming_htlc_amt
from the final node's HTLC:- MUST return a
final_incorrect_htlc_amount
error.
- MUST return a
The origin node:
- MUST ignore any extra bytes in
failuremsg
. - if the final node is returning the error:
- if the PERM bit is set:
- SHOULD fail the payment.
- otherwise:
- if the error code is understood and valid:
- MAY retry the payment. In particular,
final_expiry_too_soon
can occur if the block height has changed since sending, and in this casetemporary_node_failure
could resolve within a few seconds.
- MAY retry the payment. In particular,
- if the error code is understood and valid:
- if the PERM bit is set:
- otherwise, an intermediate hop is returning the error:
- if the NODE bit is set:
- SHOULD remove all channels connected with the erring node from consideration.
- if the PERM bit is NOT set:
- SHOULD restore the channels as it receives new
channel_update
s.
- SHOULD restore the channels as it receives new
- otherwise:
- if UPDATE is set, AND the
channel_update
is valid and more recent than thechannel_update
used to send the payment:- if
channel_update
should NOT have caused the failure:- MAY treat the
channel_update
as invalid.
- MAY treat the
- otherwise:
- SHOULD apply the
channel_update
.
- SHOULD apply the
- MAY queue the
channel_update
for broadcast.
- if
- otherwise:
- SHOULD eliminate the channel outgoing from the erring node from consideration.
- if the PERM bit is NOT set:
- SHOULD restore the channel as it receives new
channel_update
s.
- SHOULD restore the channel as it receives new
- if UPDATE is set, AND the
- SHOULD then retry routing and sending the payment.
- if the NODE bit is set:
- MAY use the data specified in the various failure types for debugging purposes.
The test vectors use the following parameters:
pubkey[0] = 0x02eec7245d6b7d2ccb30380bfbe2a3648cd7a942653f5aa340edcea1f283686619
pubkey[1] = 0x0324653eac434488002cc06bbfb7f10fe18991e35f9fe4302dbea6d2353dc0ab1c
pubkey[2] = 0x027f31ebc5462c1fdce1b737ecff52d37d75dea43ce11c74d25aa297165faa2007
pubkey[3] = 0x032c0b7cf95324a07d05398b240174dc0c2be444d96b159aa6c7f7b1e668680991
pubkey[4] = 0x02edabbd16b41c8371b92ef2f04c1185b4f03b6dcd52ba9b78d9d7c89c8f221145
nhops = 5/20
sessionkey = 0x4141414141414141414141414141414141414141414141414141414141414141
associated data = 0x4242424242424242424242424242424242424242424242424242424242424242
The following is an in-depth trace of an example of error message creation:
# node 4 is returning an error
failure_message = 2002
# creating error message
shared_secret = b5756b9b542727dbafc6765a49488b023a725d631af688fc031217e90770c328
payload = 0002200200fe0000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000
um_key = 4da7f2923edce6c2d85987d1d9fa6d88023e6c3a9c3d20f07d3b10b61a78d646
raw_error_packet = 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
# forwarding error packet
shared_secret = b5756b9b542727dbafc6765a49488b023a725d631af688fc031217e90770c328
ammag_key = 2f36bb8822e1f0d04c27b7d8bb7d7dd586e032a3218b8d414afbba6f169a4d68
stream = 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
error packet for node 4: 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
# forwarding error packet
shared_secret = 21e13c2d7cfe7e18836df50872466117a295783ab8aab0e7ecc8c725503ad02d
ammag_key = cd9ac0e09064f039fa43a31dea05f5fe5f6443d40a98be4071af4a9d704be5ad
stream = 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
error packet for node 3: 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
forwarding error packet
shared_secret = 3a6b412548762f0dbccce5c7ae7bb8147d1caf9b5471c34120b30bc9c04891cc
ammag_key = 1bf08df8628d452141d56adfd1b25c1530d7921c23cecfc749ac03a9b694b0d3
stream = 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
error packet for node 2: 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
# forwarding error packet
shared_secret = a6519e98832a0b179f62123b3567c106db99ee37bef036e783263602f3488fae
ammag_key = 59ee5867c5c151daa31e36ee42530f429c433836286e63744f2020b980302564
stream = 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
error packet for node 1: 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
# forwarding error packet
shared_secret = 53eb63ea8a3fec3b3cd433b85cd62a4b145e1dda09391b348c4e1cd36a03ea66
ammag_key = 3761ba4d3e726d8abb16cba5950ee976b84937b61b7ad09e741724d7dee12eb5
stream = 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
error packet for node 0: 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
[ FIXME: ]
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