include module type of struct include Bls12_381.Fr endinclude Ff_sig.PRIMEtype t = Bls12_381.Fr.tval zero : tval one : tval is_zero : t -> boolval is_one : t -> boolval random : ?state:Stdlib.Random.State.t -> unit -> tval non_null_random : ?state:Stdlib.Random.State.t -> unit -> tval of_bytes_exn : Stdlib.Bytes.t -> tval of_bytes_opt : Stdlib.Bytes.t -> t optionval to_bytes : t -> Stdlib.Bytes.tval of_string : string -> tval to_string : t -> stringval of_z : Z.t -> tval to_z : t -> Z.tval legendre_symbol : t -> Z.tval is_quadratic_residue : t -> boolCheck if a point, represented as a byte array, is in the field *
fft ~domain ~points performs a Fourier transform on points using domain The domain should be of the form w^{i} where w is a principal root of unity. If the domain is of size n, w must be a n-th principal root of unity. The number of points can be smaller than the domain size, but not larger. The complexity is in O(n log(m)) where n is the domain size and m the number of points. A new array of size n is allocated and is returned. The parameters are not modified.
fft_inplace ~domain ~points performs a Fourier transform on points using domain The domain should be of the form w^{i} where w is a principal root of unity. If the domain is of size n, w must be a n-th principal root of unity. The number of points must be in the same size than the domain. It does not return anything but modified the points directly. It does only perform one allocation of a scalar for the FFT. It is recommended to use this function if side-effect is acceptable.
ifft ~domain ~points performs an inverse Fourier transform on points using domain. The domain should be of the form w^{-i} (i.e the "inverse domain") where w is a principal root of unity. If the domain is of size n, w must be a n-th principal root of unity. The domain size must be exactly the same than the number of points. The complexity is O(n log(n)) where n is the domain size. A new array of size n is allocated and is returned. The parameters are not modified.
ifft_inplace ~domain ~points is the same than ifft but modifies the array points instead of returning a new array
add_inplace res a b is the same than add but writes the result in res. No allocation happens.
sub_inplace res a b is the same than sub but writes the result in res. No allocation happens.
mul_inplace res a b is the same than sub but writes the result in res. No allocation happens.
inverse_exn_inplace res a is the same than inverse_exn but writes the result in res. No allocation happens.
double_inplace res a is the same than double but writes the result in res. No allocation happens.
square_inplace res a is the same than square but writes the result in res. No allocation happens.
negate_inplace res a is the same than negate but writes the result in res. No allocation happens.
add_bulk xs returns the sum of the elements of xs by performing only one allocation for the output. This method is recommended to save the allocation overhead of using n times add.
mul_bulk xs returns the product of the elements of xs by performing only one allocation for the output. This method is recommended to save the allocation overhead of using n times mul.
compare a b compares the elements a and b based on their bytes representation
inner_product_exn a b returns the inner product of a and b, i.e. sum(a_i * b_i). Raise Invalid_argument if the arguments are not of the same length. Only two allocations are used.
Same than inner_product_exn but returns an option instead of raising an exception.
val of_int : int -> tof_int x is equivalent to of_z (Z.of_int x). If x is is negative, returns the element order - |x|.
type scalar = tval mone : tval string_of_scalar : t -> stringval encoding : t Data_encoding.encoding