Documentation ¶
Overview ¶
Package fr contains field arithmetic operations for modulus = 0x3eeb04...000001.
The API is similar to math/big (big.Int), but the operations are significantly faster (up to 20x for the modular multiplication on amd64, see also https://hackmd.io/@gnark/modular_multiplication)
The modulus is hardcoded in all the operations.
Field elements are represented as an array, and assumed to be in Montgomery form in all methods:
type Element [6]uint64
Example API signature
// Mul z = x * y mod q func (z *Element) Mul(x, y *Element) *Element
and can be used like so:
var a, b Element a.SetUint64(2) b.SetString("984896738") a.Mul(a, b) a.Sub(a, a) .Add(a, b) .Inv(a) b.Exp(b, new(big.Int).SetUint64(42))
Modulus
0x3eeb0416684d19053cb5d240ed107a284059eb647102326980dc360d0a49d7fce97f76a822c00009948a20000000001 // base 16 605248206075306171733248481581800960739847691770924913753520744034740935903401304776283802348837311170974282940417 // base 10
Index ¶
- Constants
- func Butterfly(a, b *Element)
- func Modulus() *big.Int
- func MulBy13(x *Element)
- func MulBy3(x *Element)
- func MulBy5(x *Element)
- type Element
- func (z *Element) Add(x, y *Element) *Element
- func (z *Element) Bit(i uint64) uint64
- func (z *Element) BitLen() int
- func (z *Element) Bytes() (res [Limbs * 8]byte)
- func (z *Element) Cmp(x *Element) int
- func (z *Element) Div(x, y *Element) *Element
- func (z *Element) Double(x *Element) *Element
- func (z *Element) Equal(x *Element) bool
- func (z *Element) Exp(x Element, exponent *big.Int) *Element
- func (z *Element) FitsOnOneWord() bool
- func (z *Element) FromMont() *Element
- func (z *Element) Halve()
- func (z *Element) Inverse(x *Element) *Element
- func (z *Element) IsOne() bool
- func (z *Element) IsUint64() bool
- func (z *Element) IsZero() bool
- func (z *Element) Legendre() int
- func (z *Element) LexicographicallyLargest() bool
- func (z *Element) Marshal() []byte
- func (z *Element) MarshalJSON() ([]byte, error)
- func (z *Element) Mul(x, y *Element) *Element
- func (z *Element) Neg(x *Element) *Element
- func (z *Element) NotEqual(x *Element) uint64
- func (z *Element) Select(c int, x0 *Element, x1 *Element) *Element
- func (z *Element) Set(x *Element) *Element
- func (z *Element) SetBigInt(v *big.Int) *Element
- func (z *Element) SetBytes(e []byte) *Element
- func (z *Element) SetInt64(v int64) *Element
- func (z *Element) SetInterface(i1 interface{}) (*Element, error)
- func (z *Element) SetOne() *Element
- func (z *Element) SetRandom() (*Element, error)
- func (z *Element) SetString(number string) *Element
- func (z *Element) SetUint64(v uint64) *Element
- func (z *Element) SetZero() *Element
- func (z *Element) Sqrt(x *Element) *Element
- func (z *Element) Square(x *Element) *Element
- func (z *Element) String() string
- func (z *Element) Sub(x, y *Element) *Element
- func (z *Element) Text(base int) string
- func (z *Element) ToBigInt(res *big.Int) *big.Int
- func (z Element) ToBigIntRegular(res *big.Int) *big.Int
- func (z *Element) ToMont() *Element
- func (z Element) ToRegular() Element
- func (z *Element) Uint64() uint64
- func (z *Element) UnmarshalJSON(data []byte) error
Constants ¶
const Bits = 378
Bits number bits needed to represent Element
const Bytes = Limbs * 8
Bytes number bytes needed to represent Element
const Limbs = 6
Limbs number of 64 bits words needed to represent Element
Variables ¶
This section is empty.
Functions ¶
Types ¶
type Element ¶
type Element [6]uint64
Element represents a field element stored on 6 words (uint64) Element are assumed to be in Montgomery form in all methods field modulus q =
605248206075306171733248481581800960739847691770924913753520744034740935903401304776283802348837311170974282940417
func BatchInvert ¶
BatchInvert returns a new slice with every element inverted. Uses Montgomery batch inversion trick
func NewElement ¶
NewElement returns a new Element from a uint64 value
it is equivalent to
var v NewElement v.SetUint64(...)
func (*Element) Bit ¶
Bit returns the i'th bit, with lsb == bit 0. It is the responsibility of the caller to convert from Montgomery to Regular form if needed
func (*Element) BitLen ¶
BitLen returns the minimum number of bits needed to represent z returns 0 if z == 0
func (*Element) Bytes ¶
Bytes returns the regular (non montgomery) value of z as a big-endian byte array.
func (*Element) Cmp ¶
Cmp compares (lexicographic order) z and x and returns:
-1 if z < x 0 if z == x +1 if z > x
func (*Element) FitsOnOneWord ¶
FitsOnOneWord reports whether z words (except the least significant word) are 0
func (*Element) FromMont ¶
FromMont converts z in place (i.e. mutates) from Montgomery to regular representation sets and returns z = z * 1
func (*Element) Inverse ¶
Inverse z = x⁻¹ mod q Implements "Optimized Binary GCD for Modular Inversion" https://github.com/pornin/bingcd/blob/main/doc/bingcd.pdf
func (*Element) LexicographicallyLargest ¶
LexicographicallyLargest returns true if this element is strictly lexicographically larger than its negation, false otherwise
func (*Element) Marshal ¶
Marshal returns the regular (non montgomery) value of z as a big-endian byte slice.
func (*Element) MarshalJSON ¶
MarshalJSON returns json encoding of z (z.Text(10)) If z == nil, returns null
func (*Element) Mul ¶
Mul z = x * y mod q see https://hackmd.io/@gnark/modular_multiplication
func (*Element) SetBytes ¶
SetBytes interprets e as the bytes of a big-endian unsigned integer, sets z to that value (in Montgomery form), and returns z.
func (*Element) SetInterface ¶
SetInterface converts provided interface into Element returns an error if provided type is not supported supported types: Element, *Element, uint64, int, string (interpreted as base10 integer), *big.Int, big.Int, []byte
func (*Element) SetString ¶
SetString creates a big.Int with number and calls SetBigInt on z
The number prefix determines the actual base: A prefix of ”0b” or ”0B” selects base 2, ”0”, ”0o” or ”0O” selects base 8, and ”0x” or ”0X” selects base 16. Otherwise, the selected base is 10 and no prefix is accepted.
For base 16, lower and upper case letters are considered the same: The letters 'a' to 'f' and 'A' to 'F' represent digit values 10 to 15.
An underscore character ”_” may appear between a base prefix and an adjacent digit, and between successive digits; such underscores do not change the value of the number. Incorrect placement of underscores is reported as a panic if there are no other errors.
func (*Element) Sqrt ¶
Sqrt z = √x mod q if the square root doesn't exist (x is not a square mod q) Sqrt leaves z unchanged and returns nil
func (*Element) Square ¶
Square z = x * x mod q see https://hackmd.io/@gnark/modular_multiplication
func (*Element) Text ¶
Text returns the string representation of z in the given base. Base must be between 2 and 36, inclusive. The result uses the lower-case letters 'a' to 'z' for digit values 10 to 35. No prefix (such as "0x") is added to the string. If z is a nil pointer it returns "<nil>". If base == 10 and -z fits in a uint64 prefix "-" is added to the string.
func (Element) ToBigIntRegular ¶
ToBigIntRegular returns z as a big.Int in regular form
func (*Element) Uint64 ¶
Uint64 returns the uint64 representation of x. If x cannot be represented in a uint64, the result is undefined.
func (*Element) UnmarshalJSON ¶
UnmarshalJSON accepts numbers and strings as input See Element.SetString for valid prefixes (0x, 0b, ...)
Source Files ¶
Directories ¶
Path | Synopsis |
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Package fft provides in-place discrete Fourier transform.
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Package fft provides in-place discrete Fourier transform. |
Package kzg provides a KZG commitment scheme.
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Package kzg provides a KZG commitment scheme. |
Package mimc provides MiMC hash function using Miyaguchi–Preneel construction.
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Package mimc provides MiMC hash function using Miyaguchi–Preneel construction. |
Package permutation provides an API to build permutation proofs.
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Package permutation provides an API to build permutation proofs. |
Package plookup provides an API to build plookup proofs.
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Package plookup provides an API to build plookup proofs. |
Package polynomial provides polynomial methods and commitment schemes.
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Package polynomial provides polynomial methods and commitment schemes. |