eth2.0-specs/specs/eip4844/polynomial-commitments.md

# EIP-4844 -- Polynomial Commitments

## Table of contents

<!-- TOC -->
<!-- START doctoc generated TOC please keep comment here to allow auto update -->
<!-- DON'T EDIT THIS SECTION, INSTEAD RE-RUN doctoc TO UPDATE -->

- [Introduction](#introduction)
- [Custom types](#custom-types)
- [Constants](#constants)
- [Preset](#preset)
  - [Trusted setup](#trusted-setup)
- [Helper functions](#helper-functions)
  - [BLS12-381 helpers](#bls12-381-helpers)
    - [`bls_modular_inverse`](#bls_modular_inverse)
    - [`div`](#div)
    - [`lincomb`](#lincomb)
  - [KZG](#kzg)
    - [`blob_to_kzg`](#blob_to_kzg)
    - [`verify_kzg_proof`](#verify_kzg_proof)
  - [Polynomials](#polynomials)
    - [`evaluate_polynomial_in_evaluation_form`](#evaluate_polynomial_in_evaluation_form)

<!-- END doctoc generated TOC please keep comment here to allow auto update -->
<!-- /TOC -->


## Introduction

This document specifies basic polynomial operations and KZG polynomial commitment operations as they are needed for the EIP-4844 specification. The implementations are not optimized for performance, but readability. All practical implementations should optimize the polynomial operations.

## Custom types

| Name | SSZ equivalent | Description |
| - | - | - |
| `BLSFieldElement` | `uint256` | `x < BLS_MODULUS` |
| `KZGCommitment` | `Bytes48` | Same as BLS standard "is valid pubkey" check but also allows `0x00..00` for point-at-infinity |
| `KZGProof` | `Bytes48` | Same as for `KZGCommitment` |

## Constants

| Name | Value | Notes |
| - | - | - |
| `BLS_MODULUS` | `52435875175126190479447740508185965837690552500527637822603658699938581184513` | Scalar field modulus of BLS12-381 |
| `ROOTS_OF_UNITY` | `Vector[BLSFieldElement, FIELD_ELEMENTS_PER_BLOB]` | Roots of unity of order FIELD_ELEMENTS_PER_BLOB over the BLS12-381 field |

## Preset

### Trusted setup

The trusted setup is part of the preset: during testing a `minimal` insecure variant may be used,
but reusing the `mainnet` settings in public networks is a critical security requirement.

| Name | Value |
| - | - |
| `KZG_SETUP_G2` | `Vector[G2Point, FIELD_ELEMENTS_PER_BLOB]`, contents TBD |
| `KZG_SETUP_LAGRANGE` | `Vector[KZGCommitment, FIELD_ELEMENTS_PER_BLOB]`, contents TBD |

## Helper functions

### BLS12-381 helpers

#### `bls_modular_inverse`

```python
def bls_modular_inverse(x: BLSFieldElement) -> BLSFieldElement:
    """
    Compute the modular inverse of x
    i.e. return y such that x * y % BLS_MODULUS == 1 and return 0 for x == 0
    """
    return pow(x, -1, BLS_MODULUS) if x != 0 else 0
```

#### `div`

```python
def div(x, y):
    """Divide two field elements: `x` by `y`"""
    return x * inv(y) % BLS_MODULUS
```

#### `lincomb`

```python
def lincomb(points: List[KZGCommitment], scalars: List[BLSFieldElement]) -> KZGCommitment:
    """
    BLS multiscalar multiplication. This function can be optimized using Pippenger's algorithm and variants.
    """
    r = bls.Z1
    for x, a in zip(points, scalars):
        r = bls.add(r, bls.multiply(x, a))
    return r
```

### KZG

KZG core functions. These are also defined in EIP-4844 execution specs.

#### `blob_to_kzg`

```python
def blob_to_kzg(blob: Blob) -> KZGCommitment:
    return lincomb(KZG_SETUP_LAGRANGE, blob)
```

#### `verify_kzg_proof`

```python
def verify_kzg_proof(polynomial_kzg: KZGCommitment,
                     x: BLSFieldElement,
                     y: BLSFieldElement,
                     quotient_kzg: KZGProof) -> bool:
    """Verify KZG proof that `p(x) == y` where `p(x)` is the polynomial represented by `polynomial_kzg`"""
    # Verify: P - y = Q * (X - x)
    X_minus_x = bls.add(KZG_SETUP_G2[1], bls.multiply(bls.G2, BLS_MODULUS - x))
    P_minus_y = bls.add(polynomial_kzg, bls.multiply(bls.G1, BLS_MODULUS - y))
    return bls.pairing_check([
        [P_minus_y, bls.neg(bls.G2)],
        [quotient_kzg, X_minus_x]
    ])
```

### Polynomials

#### `evaluate_polynomial_in_evaluation_form`

```python
def evaluate_polynomial_in_evaluation_form(poly: List[BLSFieldElement], x: BLSFieldElement) -> BLSFieldElement:
    """
    Evaluate a polynomial (in evaluation form) at an arbitrary point `x`
    Uses the barycentric formula:
       f(x) = (1 - x**WIDTH) / WIDTH  *  sum_(i=0)^WIDTH  (f(DOMAIN[i]) * DOMAIN[i]) / (x - DOMAIN[i])
    """
    width = len(poly)
    assert width == FIELD_ELEMENTS_PER_BLOB
    inverse_width = bls_modular_inverse(width)

    for i in range(width):
        r += div(poly[i] * ROOTS_OF_UNITY[i], (x - ROOTS_OF_UNITY[i]) )
    r = r * (pow(x, width, BLS_MODULUS) - 1) * inverse_width % BLS_MODULUS

    return r
```
Move EIP-4844 cryptography code to its own file 2022-06-22 12:13:41 +00:00			`# EIP-4844 -- Polynomial Commitments`

			`## Table of contents`

			`<!-- TOC -->`
			`<!-- START doctoc generated TOC please keep comment here to allow auto update -->`
			`<!-- DON'T EDIT THIS SECTION, INSTEAD RE-RUN doctoc TO UPDATE -->`

			`- [Introduction](#introduction)`
			`- [Custom types](#custom-types)`
			`- [Constants](#constants)`
			`- [Preset](#preset)`
			`- [Trusted setup](#trusted-setup)`
			`- [Helper functions](#helper-functions)`
			`- [BLS12-381 helpers](#bls12-381-helpers)`
			- [`bls_modular_inverse`](#bls_modular_inverse)
			- [`div`](#div)
			- [`lincomb`](#lincomb)
			`- [KZG](#kzg)`
			- [`blob_to_kzg`](#blob_to_kzg)
			- [`verify_kzg_proof`](#verify_kzg_proof)
			`- [Polynomials](#polynomials)`
			- [`evaluate_polynomial_in_evaluation_form`](#evaluate_polynomial_in_evaluation_form)

			`<!-- END doctoc generated TOC please keep comment here to allow auto update -->`
			`<!-- /TOC -->`


			`## Introduction`

			`This document specifies basic polynomial operations and KZG polynomial commitment operations as they are needed for the EIP-4844 specification. The implementations are not optimized for performance, but readability. All practical implementations should optimize the polynomial operations.`

			`## Custom types`

			`\| Name \| SSZ equivalent \| Description \|`
			`\| - \| - \| - \|`
			\| `BLSFieldElement` \| `uint256` \| `x < BLS_MODULUS` \|
			\| `KZGCommitment` \| `Bytes48` \| Same as BLS standard "is valid pubkey" check but also allows `0x00..00` for point-at-infinity \|
			\| `KZGProof` \| `Bytes48` \| Same as for `KZGCommitment` \|

			`## Constants`

			`\| Name \| Value \| Notes \|`
			`\| - \| - \| - \|`
			\| `BLS_MODULUS` \| `52435875175126190479447740508185965837690552500527637822603658699938581184513` \| Scalar field modulus of BLS12-381 \|
			\| `ROOTS_OF_UNITY` \| `Vector[BLSFieldElement, FIELD_ELEMENTS_PER_BLOB]` \| Roots of unity of order FIELD_ELEMENTS_PER_BLOB over the BLS12-381 field \|

			`## Preset`

			`### Trusted setup`

			The trusted setup is part of the preset: during testing a `minimal` insecure variant may be used,
			but reusing the `mainnet` settings in public networks is a critical security requirement.

			`\| Name \| Value \|`
			`\| - \| - \|`
			\| `KZG_SETUP_G2` \| `Vector[G2Point, FIELD_ELEMENTS_PER_BLOB]`, contents TBD \|
			\| `KZG_SETUP_LAGRANGE` \| `Vector[KZGCommitment, FIELD_ELEMENTS_PER_BLOB]`, contents TBD \|

			`## Helper functions`

			`### BLS12-381 helpers`

			#### `bls_modular_inverse`

			```python
			`def bls_modular_inverse(x: BLSFieldElement) -> BLSFieldElement:`
			`"""`
Use Python's pow() in bls_modular_inverse(). 2022-06-22 12:19:24 +00:00			`Compute the modular inverse of x`
Move EIP-4844 cryptography code to its own file 2022-06-22 12:13:41 +00:00			`i.e. return y such that x * y % BLS_MODULUS == 1 and return 0 for x == 0`
			`"""`
Use Python's pow() in bls_modular_inverse(). 2022-06-22 12:19:24 +00:00			`return pow(x, -1, BLS_MODULUS) if x != 0 else 0`
Move EIP-4844 cryptography code to its own file 2022-06-22 12:13:41 +00:00			```

			#### `div`

			```python
			`def div(x, y):`
			"""Divide two field elements: `x` by `y`"""
			`return x * inv(y) % BLS_MODULUS`
			```

			#### `lincomb`

			```python
			`def lincomb(points: List[KZGCommitment], scalars: List[BLSFieldElement]) -> KZGCommitment:`
			`"""`
			`BLS multiscalar multiplication. This function can be optimized using Pippenger's algorithm and variants.`
			`"""`
			`r = bls.Z1`
			`for x, a in zip(points, scalars):`
			`r = bls.add(r, bls.multiply(x, a))`
			`return r`
			```

			`### KZG`

			`KZG core functions. These are also defined in EIP-4844 execution specs.`

			#### `blob_to_kzg`

			```python
			`def blob_to_kzg(blob: Blob) -> KZGCommitment:`
			`return lincomb(KZG_SETUP_LAGRANGE, blob)`
			```

			#### `verify_kzg_proof`

			```python
			`def verify_kzg_proof(polynomial_kzg: KZGCommitment,`
			`x: BLSFieldElement,`
			`y: BLSFieldElement,`
			`quotient_kzg: KZGProof) -> bool:`
			"""Verify KZG proof that `p(x) == y` where `p(x)` is the polynomial represented by `polynomial_kzg`"""
			`# Verify: P - y = Q * (X - x)`
			`X_minus_x = bls.add(KZG_SETUP_G2[1], bls.multiply(bls.G2, BLS_MODULUS - x))`
			`P_minus_y = bls.add(polynomial_kzg, bls.multiply(bls.G1, BLS_MODULUS - y))`
			`return bls.pairing_check([`
			`[P_minus_y, bls.neg(bls.G2)],`
			`[quotient_kzg, X_minus_x]`
			`])`
			```

			`### Polynomials`

			#### `evaluate_polynomial_in_evaluation_form`

			```python
			`def evaluate_polynomial_in_evaluation_form(poly: List[BLSFieldElement], x: BLSFieldElement) -> BLSFieldElement:`
			`"""`
			Evaluate a polynomial (in evaluation form) at an arbitrary point `x`
			`Uses the barycentric formula:`
			`f(x) = (1 - x*WIDTH) / WIDTH sum_(i=0)^WIDTH (f(DOMAIN[i]) * DOMAIN[i]) / (x - DOMAIN[i])`
			`"""`
			`width = len(poly)`
			`assert width == FIELD_ELEMENTS_PER_BLOB`
			`inverse_width = bls_modular_inverse(width)`

			`for i in range(width):`
			`r += div(poly[i] * ROOTS_OF_UNITY[i], (x - ROOTS_OF_UNITY[i]) )`
			`r = r * (pow(x, width, BLS_MODULUS) - 1) * inverse_width % BLS_MODULUS`

			`return r`
			```