Date: Tue, 09 Jan 2024 15:31:37 +0000
To: "bitcoin-dev@lists.linuxfoundation.org"
 <bitcoin-dev@lists.linuxfoundation.org>
From: Tom Briar <tombriar11@protonmail.com>
Message-ID: <IFgPQiCptuVM6I5AsCE6VFrPMsGzBMK3x78GHlupJj12-rBloASYdafdBzyjSKC0H0EWLG2NNBzu1wEyYyyl1VzMmjW3nO7M-9OJpMxoEMM=@protonmail.com>
In-Reply-To: <ZZgeA1KPUbLtQjoT@camus>
References: <WJoM7dyrk0o8ujOZOo462r66wS2Kl3L1ZZRodvaLK-HKEUc90yvwOqXbUUrGbV1lk6cOywTqLoCyHzk2Tm3TtBFyUL0NZ6D7v9NmTXypJPA=@protonmail.com>
 <KSmH1MBTPLuXMF4TWbWq6vaft_K_7IZS2YcoZ1iHwtHY06It1DjExVgSdrLBMQZA8mLGz8xdOzyXRHAZ2qCAugwG8gMtEGsGj-XNTPN0v0w=@protonmail.com>
 <ZPHtgiJQ4Yqrr941@camus> <ZPdswQ7uAJr35YbC@petertodd.org>
 <hd13VCUTiTaX_Z4oeZpzwjdVOcmkbcg-kgfThk9b1LUt2YUCEXrwVuEq8BiNWtfzeAafo6GdsrFzGg3pQI5kSjuRc4TtFGmRndvVukAwAiY=@protonmail.com>
 <xk6TD_XVlJodelVrD6HTzj-YZ6MaRJ8lU_ugEddOixoQfCmn59oQYKw-QZOwjL7b_LENm1Jza4NtBKAaXWqwHwcOOyvwlUbJuKw7f5lkm1s=@protonmail.com>
 <ZZgeA1KPUbLtQjoT@camus>
Feedback-ID: 43655394:user:proton
MIME-Version: 1.0
Content-Type: text/plain; charset=utf-8
Content-Transfer-Encoding: quoted-printable
Subject: Re: [bitcoin-dev] Compressed Bitcoin Transactions
Precedence: list

Hi,

After reviewing all the feedback and writing a reference implementation, I =
have linked the updated schema and a Draft PR for a reference Implementatio=
n to Bitcoin Core.

Some of the major changes consist of:=20

Removing the grinding of the nLocktime in favor of a relative block height,=
 which all of the Compressed Inputs use.
And the use of a second kind of Variable Integer.


Compressed Transaction Schema:

compressed_transactions.md

Reference Impl/Draft PR:

https://github.com/bitcoin/bitcoin/pull/29134

Thanks-
Tom.

=3D=3D=3D begin compressed_transactions.md =3D=3D=3D

# Compressed Transaction Schema
By (Tom Briar) and (Andrew Poelstra)

## 1. Abstract

With this Transaction Compression Schema we use several methods to compress=
 transactions,
including dropping data and recovering it on decompression by grinding unti=
l we obtain
valid signatures.

The bulk of our size savings come from replacing the prevout of each input =
by a block
height and index. This requires the decompression to have access to the blo=
ckchain, and
also means that compression is ineffective for transactions that spend unco=
nfirmed or
insufficiently confirmed outputs.

Even without compression, Taproot keyspends are very small: as witness data=
 they
include only a single 64/65-byte signature and do not repeat the public key=
 or
any other metadata. By using pubkey recovery, we obtain Taproot-like compre=
ssion
for legacy and Segwit transactions.

The main applications for this schema are for steganography, satellite/radi=
o broadcast, and
other low bandwidth channels with a high CPU availability on decompression.=
 We
assume users have some ability to shape their transactions to improve their
compressibility, and therefore give special treatment to certain transactio=
n forms.

This schema is easily reversible except for compressing the Txid/Vout input=
 pairs(Method 4).
Compressing the input Txid/Vout is optional, and without it still gleans 50=
% of the
total compression. This allows for the additional use case of P2P communica=
tion.

## 2. Methods

The four main methods to achieve a lower transactions size are:

1. packing transaction metadata before the transaction and each of its inpu=
ts and
outputs to determine the structure of the following data.
2. replacing 32-bit numeric values with either variable-length integers (Va=
rInts) or compact-integers (CompactSizes).
3. using compressed signatures and public key recovery upon decompression.
4. replacing the 36-byte txid/vout pair with a blockheight and output index=
.

Method 4 will cause the compressed transaction to be undecompressable if a =
block
reorg occurs at or before the block it's included in. Therefore, we'll only=
 compress
the Txid if the transaction input is at least one hundred blocks old.


## 3 Schema

### 3.1 Primitives

| Name             | Width     | Description |
|------------------|-----------|-------------|
| CompactSize      | 1-5 Bytes | For 0-253, encode the value directly in on=
e byte. For 254-65535, encode 254 followed by 2 little-endian bytes. For 65=
536-(2^32-1), encode 255 followed by 4 little-endian bytes. |
| CompactSize flag | 2 Bits    | 1, 2 or 3 indicate literal values. 0 indic=
ates that the value will be encoded in a later CompactInt. |
| VarInt           | 1+ Bytes  | 7-bit little-endian encoding, with each 7-=
bit word encoded in a byte. The highest bit of each byte is 1 if more bytes=
 follow, and 0 for the last byte. |
| VLP-Bytestream   | 2+ Bytes  | A VarInt Length Prefixed Bytestream. Has a=
 VarInt prefixed to determine the length. |

### 3.2 General Schema

| Name                           | Width           | Description |
|--------------------------------|-----------------|-------------|
| Transaction Metadata           | 1 Byte    | Information on the structure=
 of the transaction. See Section 3.3. |
| Version                        | 0-5 Bytes | An optional CompactSize cont=
aining the transactions version. |
| Input Count                    | 0-5 Bytes | An optional CompactSize cont=
aining the transactions input count. |
| Output Count                   | 0-5 Bytes | An optional CompactSize cont=
aining the transactions output count. |
| LockTime                       | 0-5 Bytes | An optional CompactSize cont=
aining the transaction LockTime if its non zero. |
| Minimum Blockheight            | 1-5 Bytes | A VarInt containing the Mini=
mum Blockheight of which the transaction locktime and input blockheights ar=
e given as offsets. |
| Input Metadata+Output Metadata | 1+ Bytes  | A Encoding containing metada=
ta on all the inputs and then all the outputs of the transaction. For each =
input see Section 3.4, for each output see Section 3.5. |
| Input Data                     | 66+ Bytes | See Section 3.6 for each inp=
ut. |
| Output Data                    | 3+ Bytes  | See Section 3.7 for each out=
put. |

For the four CompactSize listed above we could use a more compact bit encod=
ing for these but they are already a fall back for the bit encoding of the =
Transaction Metadata.

### 3.3 Transaction Metadata

| Name         | Width  | Description |
|--------------|--------|-------------|
| Version      | 2 Bits | A CompactSize flag for the transaction version. |
| Input Count  | 2 Bits | A CompactSize flag for the transaction input coun=
t. |
| Output Count | 2 Bits | A CompactSize flag for the transaction output cou=
nt. |
| LockTime     | 1 Bit  | A Boolean to indicate if the transaction has a Lo=
ckTime. |

### 3.4 Input Metadata

| Name                 | Width  | Description |
|----------------------|--------|-------------|
| Compressed Signature | 1 Bit  | Signature compression flag. For P2TR: 1 f=
or keyspend, 0 for scriptspend; For P2SH: 0 for p2sh, 1 for p2sh-wpkh. |
| Standard Hash        | 1 Bit  | A flag to determine if this Input's Signa=
ture Hash Type is standard (0x00 for Taproot, 0x01 for Legacy/Segwit). |
| Standard Sequence    | 2 Bits | A CompactSize flag for the inputs sequenc=
e. Encode literal values as follows: 1 =3D 0x00000000, 2 =3D 0xFFFFFFFE, 3 =
=3D 0xFFFFFFFF. |

### 3.5.1 Output Metadata

| Name                | Width  | Description |
|---------------------|--------|-------------|
| Encoded Script Type | 3 Bits | Encoded Script Type. |

#### 3.5.2 Script Type encoding

| Script Type                | Value |
|----------------------------|-------|
| Uncompressed P2PK          | 0b000 |
| Compressed P2PK            | 0b001 |
| P2PKH                      | 0b010 |
| P2SH                       | 0b011 |
| P2WSH                      | 0b100 |
| P2WPKH                     | 0b101 |
| P2TR                       | 0b110 |
| Uncompressed Custom Script | 0b111 |

### 3.6 Input Data

| Name                    | Width     | Description |
|-------------------------|-----------|-------------|
| Sequence                | 0-5 Bytes | An Optional VarInt containing the s=
equence if it was non-standard. |
| Txid Blockheight        | 1-5 Bytes | A VarInt Either containing 0 if thi=
s an uncompressed input, or it contains the offset from Minimum Blockheight=
 for this Txid. |
| Txid/Signature Data     | 65+ Bytes | Txid/Signatures are determined to b=
e uncompressed either by the output script of the previous transaction, or =
if the Txid Blockheight is zero. For each Compressed Txid/Signature See Sec=
tion 3.6.1. For each Uncompressed Txid/Signature See Section 3.6.2. |

### 3.6.1 Compressed Txid/Signature Data

| Name              | Width     | Description |
|-------------------|-----------|-------------|
| Txid Block Index  | 1-5 Bytes | A VarInt containing the flattened index f=
rom the Txid Blockheight for the Vout. |
| Signature         | 64 Bytes  | Contains the 64 byte signature. |
| Hash Type         | 0-1 Bytes | An Optional Byte containing the Hash Type=
 if it was non-standard.|

### 3.6.2 Uncompressed Txid/Signature Data

| Name      | Width     | Description |
|-----------|-----------|-------------|
| Txid      | 32 Bytes  | Contains the 32 byte Txid. |
| Vout      | 1-5 Bytes | A CompactSize Containing the Vout of the Txid. |
| Signature | 2+ Bytes  | A VLP-Bytestream containing the signature. |

### 3.7 Output Data

| Name          | Width     | Description |
|---------------|-----------|-------------|
| Output Script | 2+ Bytes  | A VLP-Bytestream containing the output script=
. |
| Amount        | 1-9 Bytes | A VarInt containing the output amount. |

## 4 Ideal Transaction

The target transaction for the most optimal compression was chosen
based off the most common transactions that are likely to be used
for purposes that requires the best compression.

| Field           | Requirements                      | Possible Savings   =
               |
|-----------------|-----------------------------------|--------------------=
---------------|
| Version         | Less than four                    | 30 Bits            =
               |
| Input Count     | Less then four                    | 30 Bits            =
               |
| Output Count    | Less then four                    | 30 Bits            =
               |
| LockTime        | 0                                 | 30 Bits            =
               |
| Input Sequence  | 0x00, 0xFFFFFFFE, or 0xFFFFFFFF   | 62 Bits For Each In=
put            |
| Input Txid      | Compressed Outpoint               | 23-31 Bytes For Eac=
h Input        |
| Input Vout      | Compressed Outpoint               | (-1)-3 Bytes For Ea=
ch Input       |
| Input Signature | Non-custom Script Signing         | 40-72 Bytes For Eac=
h Legacy Input |
| Input Hash Type | 0x00 for Taproot, 0x01 for Legacy | 7 Bits For Each Inp=
ut             |
| Output Script   | Non-custom Scripts                | 2-5 Bytes For Each =
Output         |
| Output Amount   | No Restrictions                   | (-1)-7 Bytes For Ea=
ch Output      |

## 5 Test Vectors

| Transaction              | Before Compression | Possible Savings         =
| After Compression |
|--------------------------|--------------------|--------------------------=
|-------------------|
| 2-(input/output) Taproot | 312 Bytes          | 78-124 Bytes and 2 Bits  =
| 190-226 Bytes     |
| 2-(input/output) Legacy  | 394 Bytes          | 118-196 Bytes and 2 Bits =
| 176-244 Bytes     |

Taproot (Uncompressed)

020000000001028899af77861ede1ee384c333974722c96eabba8889506725b00735fc35ba4=
1680000000000000000008899af77861ede1ee384c333974722c96eabba8889506725b00735=
fc35ba41680000000000000000000288130000000000002251206b10142cffb29e9d83f63a7=
7a428be41f96bd9b6ccc9889e4ec74927058b41dda00f000000000000225120dd00ac641dc0=
f399e62a6ed6300aba1ec5fa4b3aeedf1717901e0d49d980efd20140f3d9bcc844eab7055a1=
68a62f65b8625e3853fad8f834d5c82fdf23100b7b871cf48c2c956e7d76cdd367bbfefe496=
c426e64dcfeaef800ab9893142050714b6014081c15fe5ed6b8a0c0509e871dfbb7784ddb22=
dd33b47f3ad1a3b271d29acfe76b5152b53ed29a7f6ea27cb4f5882064da07e8430aacafab8=
9a334b32780fcb2700000000


Taproot (Compressed)

2ab0dd0177d801ad1cf3d9bcc844eab7055a168a62f65b8625e3853fad8f834d5c82fdf2310=
0b7b871cf48c2c956e7d76cdd367bbfefe496c426e64dcfeaef800ab9893142050714b601ad=
1c81c15fe5ed6b8a0c0509e871dfbb7784ddb22dd33b47f3ad1a3b271d29acfe76b5152b53e=
d29a7f6ea27cb4f5882064da07e8430aacafab89a334b32780fcb276b10142cffb29e9d83f6=
3a77a428be41f96bd9b6ccc9889e4ec74927058b41dda608dd00ac641dc0f399e62a6ed6300=
aba1ec5fa4b3aeedf1717901e0d49d980efd29e20


Legacy (Uncompressed)

02000000000102c583fe4f934a0ed87e4d082cd52967cc774b943fbb2e21378ec18b926b8dc=
549000000000000000000c583fe4f934a0ed87e4d082cd52967cc774b943fbb2e21378ec18b=
926b8dc5490000000000000000000288130000000000002251206b10142cffb29e9d83f63a7=
7a428be41f96bd9b6ccc9889e4ec74927058b41dda00f000000000000225120dd00ac641dc0=
f399e62a6ed6300aba1ec5fa4b3aeedf1717901e0d49d980efd202473044022000d1c81efcf=
6d20d87253749bcef8bf1be7ba51ccdf7a3b328174ea874226c3c02202d810c20f92d49c821=
eaa6e3a9ec7d764e0e71006e572d6ea96b631bd921767c0121037833d05665f3b21c479583e=
e12c6c573d1f25977dedfae12c70c18ec9dd4618702473044022000d1c81efcf6d20d872537=
49bcef8bf1be7ba51ccdf7a3b328174ea874226c3c02202d810c20f92d49c821eaa6e3a9ec7=
d764e0e71006e572d6ea96b631bd921767c0121037833d05665f3b21c479583ee12c6c573d1=
f25977dedfae12c70c18ec9dd4618700000000


Legacy (Compressed)(Uncompressed Txid/Vout)

2a8efefefe7f44d800c583fe4f934a0ed87e4d082cd52967cc774b943fbb2e21378ec18b926=
b8dc549006c0002473044022000d1c81efcf6d20d87253749bcef8bf1be7ba51ccdf7a3b328=
174ea874226c3c02202d810c20f92d49c821eaa6e3a9ec7d764e0e71006e572d6ea96b631bd=
921767c0121037833d05665f3b21c479583ee12c6c573d1f25977dedfae12c70c18ec9dd461=
8700c583fe4f934a0ed87e4d082cd52967cc774b943fbb2e21378ec18b926b8dc549006c000=
2473044022000d1c81efcf6d20d87253749bcef8bf1be7ba51ccdf7a3b328174ea874226c3c=
02202d810c20f92d49c821eaa6e3a9ec7d764e0e71006e572d6ea96b631bd921767c0121037=
833d05665f3b21c479583ee12c6c573d1f25977dedfae12c70c18ec9dd461876b10142cffb2=
9e9d83f63a77a428be41f96bd9b6ccc9889e4ec74927058b41dda608dd00ac641dc0f399e62=
a6ed6300aba1ec5fa4b3aeedf1717901e0d49d980efd29e20


=3D=3D=3D end compressed_transactions.md =3D=3D=3D

On Friday, January 5th, 2024 at 10:19 AM, Andrew Poelstra via bitcoin-dev <=
bitcoin-dev@lists.linuxfoundation.org> wrote:


> Thanks Tom.
>=20
> It looks like you posted a text-scrape of the rendered markdown, which
> is hard to read. For posterity here is the full text.
>=20
> Best
> Andrew
>=20
>=20
> =3D=3D=3D begin compressed_transactions.md =3D=3D=3D
>=20
> # Compressed Transaction Schema
> By (Tom Briar) and (Andrew Poelstra)
>=20
> ## 1. Abstract
>=20
> With this Transaction Compression Schema we use several methods to compre=
ss transactions,
> including dropping data and recovering it on decompression by grinding un=
til we obtain
> valid signatures.
>=20
> The bulk of our size savings come from replacing the prevout of each inpu=
t by a block
> height and index. This requires the decompression to have access to the b=
lockchain, and
> also means that compression is ineffective for transactions that spend un=
confirmed or
> insufficiently confirmed outputs.
>=20
> Even without compression, Taproot keyspends are very small: as witness da=
ta they
> include only a single 64/65-byte signature and do not repeat the public k=
ey or
> any other metadata. By using pubkey recovery, we obtain Taproot-like comp=
ression
> for legacy and Segwit transactions.
>=20
> The main applications for this schema are for steganography, satellite/ra=
dio broadcast, and
> other low bandwidth channels with a high CPU availability on decompressio=
n. We
> assume users have some ability to shape their transactions to improve the=
ir
> compressibility, and therefore give special treatment to certain transact=
ion forms.
>=20
> This schema is easily reversible except for compressing the Txid/Vout inp=
ut pairs(Method 4).
> Compressing the input Txid/Vout is optional, and without it still gleans =
50% of the
> total compression. This allows for the additional use case of P2P communi=
cation.
>=20
> ## 2. Methods
>=20
> The four main methods to achieve a lower transactions size are:
>=20
> 1. packing transaction metadata before the transaction and each of its in=
puts and
> outputs to determine the structure of the following data.
> 2. replacing 32-bit numeric values with either variable-length integers (=
VarInts) or compact-integers (CompactSizes).
> 3. using compressed signatures and public key recovery upon decompression=
.
> 4. replacing the 36-byte txid/vout pair with a blockheight and output ind=
ex.
>=20
> Method 4 will cause the compressed transaction to be undecompressable if =
a block
> reorg occurs at or before the block it's included in. Therefore, we'll on=
ly compress
> the Txid if the transaction input is at least one hundred blocks old.
>=20
>=20
> ## 3 Schema
>=20
> ### 3.1 Primitives
>=20
> Name
>=20
> Width
>=20
> Description
>=20
> CompactSize
>=20
> 1-5 Bytes
>=20
> For 0-253, encode the value directly in one byte. For 254-65535, encode 2=
54 followed by 2 little-endian bytes. For 65536-(2^32-1), encode 255 follow=
ed by 4 little-endian bytes.
>=20
> CompactSize flag
>=20
> 2 Bits
>=20
> 1, 2 or 3 indicate literal values. 0 indicates that the value will be enc=
oded in a later CompactInt.
>=20
> VarInt
>=20
> 1+ Bytes
>=20
> 7-bit little-endian encoding, with each 7-bit word encoded in a byte. The=
 highest bit of each byte is 1 if more bytes follow, and 0 for the last byt=
e.
>=20
> VLP-Bytestream
>=20
> 2+ Bytes
>=20
> A VarInt Length Prefixed Bytestream. Has a VarInt prefixed to determine t=
he length.
>=20
> ### 3.2 General Schema
>=20
> Name
>=20
> Width
>=20
> Description
>=20
> --------------------------------
>=20
> -----------------
>=20
> -------------
>=20
> Transaction Metadata
>=20
> 1 Byte
>=20
> Information on the structure of the transaction. See Section 3.3.
>=20
> Version
>=20
> 0-5 Bytes
>=20
> An optional CompactSize containing the transactions version.
>=20
> Input Count
>=20
> 0-5 Bytes
>=20
> An optional CompactSize containing the transactions input count.
>=20
> Output Count
>=20
> 0-5 Bytes
>=20
> An optional CompactSize containing the transactions output count.
>=20
> LockTime
>=20
> 0-5 Bytes
>=20
> An optional CompactSize containing the transaction LockTime if its non ze=
ro.
>=20
> Minimum Blockheight
>=20
> 1-5 Bytes
>=20
> A VarInt containing the Minimum Blockheight of which the transaction lock=
time and input blockheights are given as offsets.
>=20
> Input Metadata+Output Metadata
>=20
> 1+ Bytes
>=20
> A Encoding containing metadata on all the inputs and then all the outputs=
 of the transaction. For each input see Section 3.4, for each output see Se=
ction 3.5.
>=20
> Input Data
>=20
> 66+ Bytes
>=20
> See Section 3.6 for each input.
>=20
> Output Data
>=20
> 3+ Bytes
>=20
> See Section 3.7 for each output.
>=20
> For the four CompactSize listed above we could use a more compact bit enc=
oding for these but they are already a fall back for the bit encoding of th=
e Transaction Metadata.
>=20
> ### 3.3 Transaction Metadata
>=20
> Name
>=20
> Width
>=20
> Description
>=20
> --------------
>=20
> --------
>=20
> -------------
>=20
> Version
>=20
> 2 Bits
>=20
> A CompactSize flag for the transaction version.
>=20
> Input Count
>=20
> 2 Bits
>=20
> A CompactSize flag for the transaction input count.
>=20
> Output Count
>=20
> 2 Bits
>=20
> A CompactSize flag for the transaction output count.
>=20
> LockTime
>=20
> 1 Bit
>=20
> A Boolean to indicate if the transaction has a LockTime.
>=20
> ### 3.4 Input Metadata
>=20
> Name
>=20
> Width
>=20
> Description
>=20
> ----------------------
>=20
> --------
>=20
> -------------
>=20
> Compressed Signature
>=20
> 1 Bit
>=20
> Signature compression flag. For P2TR: 1 for keyspend, 0 for scriptspend; =
For P2SH: 0 for p2sh, 1 for p2sh-wpkh.
>=20
> Standard Hash
>=20
> 1 Bit
>=20
> A flag to determine if this Input's Signature Hash Type is standard (0x00=
 for Taproot, 0x01 for Legacy/Segwit).
>=20
> Standard Sequence
>=20
> 2 Bits
>=20
> A CompactSize flag for the inputs sequence. Encode literal values as foll=
ows: 1 =3D 0x00000000, 2 =3D 0xFFFFFFFE, 3 =3D 0xFFFFFFFF.
>=20
> ### 3.5.1 Output Metadata
>=20
> Name
>=20
> Width
>=20
> Description
>=20
> ---------------------
>=20
> --------
>=20
> -------------
>=20
> Encoded Script Type
>=20
> 3 Bits
>=20
> Encoded Script Type.
>=20
> #### 3.5.2 Script Type encoding
>=20
> Script Type
>=20
> Value
>=20
> ----------------------------
>=20
> -------
>=20
> Uncompressed P2PK
>=20
> 0b000
>=20
> Compressed P2PK
>=20
> 0b001
>=20
> P2PKH
>=20
> 0b010
>=20
> P2SH
>=20
> 0b011
>=20
> P2WSH
>=20
> 0b100
>=20
> P2WPKH
>=20
> 0b101
>=20
> P2TR
>=20
> 0b110
>=20
> Uncompressed Custom Script
>=20
> 0b111
>=20
> ### 3.6 Input Data
>=20
> Name
>=20
> Width
>=20
> Description
>=20
> -------------------------
>=20
> -----------
>=20
> -------------
>=20
> Sequence
>=20
> 0-5 Bytes
>=20
> An Optional VarInt containing the sequence if it was non-standard.
>=20
> Txid Blockheight
>=20
> 1-5 Bytes
>=20
> A VarInt Either containing 0 if this an uncompressed input, or it contain=
s the offset from Minimum Blockheight for this Txid.
>=20
> Txid/Signature Data
>=20
> 65+ Bytes
>=20
> Txid/Signatures are determined to be uncompressed either by the output sc=
ript of the previous transaction, or if the Txid Blockheight is zero. For e=
ach Compressed Txid/Signature See Section 3.6.1. For each Uncompressed Txid=
/Signature See Section 3.6.2.
>=20
> ### 3.6.1 Compressed Txid/Signature Data
>=20
> Name
>=20
> Width
>=20
> Description
>=20
> -------------------
>=20
> -----------
>=20
> -------------
>=20
> Txid Block Index
>=20
> 1-5 Bytes
>=20
> A VarInt containing the flattened index from the Txid Blockheight for the=
 Vout.
>=20
> Signature
>=20
> 64 Bytes
>=20
> Contains the 64 byte signature.
>=20
> Hash Type
>=20
> 0-1 Bytes
>=20
> An Optional Byte containing the Hash Type if it was non-standard.
>=20
> ### 3.6.2 Uncompressed Txid/Signature Data
>=20
> Name
>=20
> Width
>=20
> Description
>=20
> -----------
>=20
> -----------
>=20
> -------------
>=20
> Txid
>=20
> 32 Bytes
>=20
> Contains the 32 byte Txid.
>=20
> Vout
>=20
> 1-5 Bytes
>=20
> A CompactSize Containing the Vout of the Txid.
>=20
> Signature
>=20
> 2+ Bytes
>=20
> A VLP-Bytestream containing the signature.
>=20
> ### 3.7 Output Data
>=20
> Name
>=20
> Width
>=20
> Description
>=20
> ---------------
>=20
> -----------
>=20
> -------------
>=20
> Output Script
>=20
> 2+ Bytes
>=20
> A VLP-Bytestream containing the output script.
>=20
> Amount
>=20
> 1-9 Bytes
>=20
> A VarInt containing the output amount.
>=20
> ## 4 Ideal Transaction
>=20
> The target transaction for the most optimal compression was chosen
>=20
> based off the most common transactions that are likely to be used
>=20
> for purposes that requires the best compression.
>=20
> Field
>=20
> Requirements
>=20
> Possible Savings
>=20
> -----------------
>=20
> -----------------------------------
>=20
> -----------------------------------
>=20
> Version
>=20
> Less than four
>=20
> 30 Bits
>=20
> Input Count
>=20
> Less then four
>=20
> 30 Bits
>=20
> Output Count
>=20
> Less then four
>=20
> 30 Bits
>=20
> LockTime
>=20
> 0
>=20
> 30 Bits
>=20
> Input Sequence
>=20
> 0x00, 0xFFFFFFFE, or 0xFFFFFFFF
>=20
> 62 Bits For Each Input
>=20
> Input Txid
>=20
> Compressed Outpoint
>=20
> 23-31 Bytes For Each Input
>=20
> Input Vout
>=20
> Compressed Outpoint
>=20
> (-1)-3 Bytes For Each Input
>=20
> Input Signature
>=20
> Non-custom Script Signing
>=20
> 40-72 Bytes For Each Legacy Input
>=20
> Input Hash Type
>=20
> 0x00 for Taproot, 0x01 for Legacy
>=20
> 7 Bits For Each Input
>=20
> Output Script
>=20
> Non-custom Scripts
>=20
> 2-5 Bytes For Each Output
>=20
> Output Amount
>=20
> No Restrictions
>=20
> (-1)-7 Bytes For Each Output
>=20
> ## 5 Test Vectors
>=20
> Transaction
>=20
> Before Compression
>=20
> Possible Savings
>=20
> --------------------------
>=20
> --------------------
>=20
> --------------------------
>=20
> 2-(input/output) Taproot
>=20
> 312 Bytes
>=20
> 78-124 Bytes and 2 Bits
>=20
> 2-(input/output) Legacy
>=20
> 394 Bytes
>=20
> 118-196 Bytes and 2 Bits
>=20
> Taproot (Uncompressed)
>=20
> ```
>=20
> 020000000001028899af77861ede1ee384c333974722c96eabba8889506725b00735fc35b=
a41680000000000000000008899af77861ede1ee384c333974722c96eabba8889506725b007=
35fc35ba41680000000000000000000288130000000000002251206b10142cffb29e9d83f63=
a77a428be41f96bd9b6ccc9889e4ec74927058b41dda00f000000000000225120dd00ac641d=
c0f399e62a6ed6300aba1ec5fa4b3aeedf1717901e0d49d980efd20140f3d9bcc844eab7055=
a168a62f65b8625e3853fad8f834d5c82fdf23100b7b871cf48c2c956e7d76cdd367bbfefe4=
96c426e64dcfeaef800ab9893142050714b6014081c15fe5ed6b8a0c0509e871dfbb7784ddb=
22dd33b47f3ad1a3b271d29acfe76b5152b53ed29a7f6ea27cb4f5882064da07e8430aacafa=
b89a334b32780fcb2700000000
>=20
> ```
>=20
> Taproot (Compressed)
>=20
> ```
>=20
> 2a81de3177d8019c2ef3d9bcc844eab7055a168a62f65b8625e3853fad8f834d5c82fdf23=
100b7b871cf48c2c956e7d76cdd367bbfefe496c426e64dcfeaef800ab9893142050714b601=
9c2e81c15fe5ed6b8a0c0509e871dfbb7784ddb22dd33b47f3ad1a3b271d29acfe76b5152b5=
3ed29a7f6ea27cb4f5882064da07e8430aacafab89a334b32780fcb276b10142cffb29e9d83=
f63a77a428be41f96bd9b6ccc9889e4ec74927058b41dd8827dd00ac641dc0f399e62a6ed63=
00aba1ec5fa4b3aeedf1717901e0d49d980efd2a01f
>=20
> ```
>=20
> Legacy (Uncompressed)
>=20
> ```
>=20
> 02000000000102c583fe4f934a0ed87e4d082cd52967cc774b943fbb2e21378ec18b926b8=
dc549000000000000000000c583fe4f934a0ed87e4d082cd52967cc774b943fbb2e21378ec1=
8b926b8dc5490000000000000000000288130000000000002251206b10142cffb29e9d83f63=
a77a428be41f96bd9b6ccc9889e4ec74927058b41dda00f000000000000225120dd00ac641d=
c0f399e62a6ed6300aba1ec5fa4b3aeedf1717901e0d49d980efd202473044022000d1c81ef=
cf6d20d87253749bcef8bf1be7ba51ccdf7a3b328174ea874226c3c02202d810c20f92d49c8=
21eaa6e3a9ec7d764e0e71006e572d6ea96b631bd921767c0121037833d05665f3b21c47958=
3ee12c6c573d1f25977dedfae12c70c18ec9dd4618702473044022000d1c81efcf6d20d8725=
3749bcef8bf1be7ba51ccdf7a3b328174ea874226c3c02202d810c20f92d49c821eaa6e3a9e=
c7d764e0e71006e572d6ea96b631bd921767c0121037833d05665f3b21c479583ee12c6c573=
d1f25977dedfae12c70c18ec9dd4618700000000
>=20
> ```
>=20
> Legacy (Compressed)
>=20
> ```
>=20
> 2ad1e53044d801ae276c0002473044022000d1c81efcf6d20d87253749bcef8bf1be7ba51=
ccdf7a3b328174ea874226c3c02202d810c20f92d49c821eaa6e3a9ec7d764e0e71006e572d=
6ea96b631bd921767c0121037833d05665f3b21c479583ee12c6c573d1f25977dedfae12c70=
c18ec9dd461870001ae276c0002473044022000d1c81efcf6d20d87253749bcef8bf1be7ba5=
1ccdf7a3b328174ea874226c3c02202d810c20f92d49c821eaa6e3a9ec7d764e0e71006e572=
d6ea96b631bd921767c0121037833d05665f3b21c479583ee12c6c573d1f25977dedfae12c7=
0c18ec9dd46187006b10142cffb29e9d83f63a77a428be41f96bd9b6ccc9889e4ec74927058=
b41dd8827dd00ac641dc0f399e62a6ed6300aba1ec5fa4b3aeedf1717901e0d49d980efd2a0=
1f
>=20
> ```
>=20
> --
>=20
> Andrew Poelstra
>=20
> Director of Research, Blockstream
>=20
> Email: apoelstra at wpsoftware.net
>=20
> Web: https://www.wpsoftware.net/andrew
>=20
> The sun is always shining in space
>=20
> -Justin Lewis-Webster
>=20
> _______________________________________________
> bitcoin-dev mailing list
> bitcoin-dev@lists.linuxfoundation.org
> https://lists.linuxfoundation.org/mailman/listinfo/bitcoin-dev