Internet Research Task Force (IRTF)                        H. de Valence
Request for Comments: 9496
Category: Informational                                         J. Grigg
ISSN: 2070-1721
                                                              M. Hamburg

                                                            I. Lovecruft

                                                           G. Tankersley

                                                             F. Valsorda
                                                           November
                                                           December 2023

                  The ristretto255 and decaf448 Groups

Abstract

   This memo specifies two prime-order groups, ristretto255 and
   decaf448, suitable for safely implementing higher-level and complex
   cryptographic protocols.  The ristretto255 group can be implemented
   using Curve25519, allowing existing Curve25519 implementations to be
   reused and extended to provide a prime-order group.  Likewise, the
   decaf448 group can be implemented using edwards448.

   This document is a product of the Crypto Forum Research Group (CFRG)
   in the IRTF.

Status of This Memo

   This document is not an Internet Standards Track specification; it is
   published for informational purposes.

   This document is a product of the Internet Research Task Force
   (IRTF).  The IRTF publishes the results of Internet-related research
   and development activities.  These results might not be suitable for
   deployment.  This RFC represents the consensus of the Crypto Forum
   Research Group of the Internet Research Task Force (IRTF).  Documents
   approved for publication by the IRSG are not candidates for any level
   of Internet Standard; see Section 2 of RFC 7841.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   https://www.rfc-editor.org/info/rfc9496.

Copyright Notice

   Copyright (c) 2023 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

   This document is subject to BCP 78 and the IETF Trust's Legal
   Provisions Relating to IETF Documents
   (https://trustee.ietf.org/license-info) in effect on the date of
   publication of this document.  Please review these documents
   carefully, as they describe your rights and restrictions with respect
   to this document.

Table of Contents

   1.  Introduction
   2.  Notation and Conventions Used in This Document
     2.1.  Negative Field Elements
     2.2.  Constant-Time Operations
   3.  The Group Abstraction
   4.  ristretto255
     4.1.  Implementation Constants
     4.2.  Square Root of a Ratio of Field Elements
     4.3.  ristretto255 Group Operations
       4.3.1.  Decode
       4.3.2.  Encode
       4.3.3.  Equals
       4.3.4.  Element Derivation
     4.4.  Scalar Field
   5.  decaf448
     5.1.  Implementation Constants
     5.2.  Square Root of a Ratio of Field Elements
     5.3.  decaf448 Group Operations
       5.3.1.  Decode
       5.3.2.  Encode
       5.3.3.  Equals
       5.3.4.  Element Derivation
     5.4.  Scalar Field
   6.  API Considerations
   7.  IANA Considerations
   8.  Security Considerations
   9.  References
     9.1.  Normative References
     9.2.  Informative References
   Appendix A.  Test Vectors for ristretto255
     A.1.  Multiples of the Generator
     A.2.  Invalid Encodings
     A.3.  Group Elements from Uniform Byte Strings
     A.4.  Square Root of a Ratio of Field Elements
   Appendix B.  Test Vectors for decaf448
     B.1.  Multiples of the Generator
     B.2.  Invalid Encodings
     B.3.  Group Elements from Uniform Byte Strings
   Acknowledgements
   Authors' Addresses

1.  Introduction

   Decaf [Decaf] is a technique for constructing prime-order groups with
   nonmalleable encodings from non-prime-order elliptic curves.
   Ristretto extends this technique to support cofactor-8 curves such as
   Curve25519 [RFC7748].  In particular, this allows an existing
   Curve25519 library to provide a prime-order group with only a thin
   abstraction layer.

   Many group-based cryptographic protocols require the number of
   elements in the group (the group order) to be prime.  Prime-order
   groups are useful because every non-identity element of the group is
   a generator of the entire group.  This means the group has a cofactor
   of 1, and all elements are equivalent from the perspective of
   hardness of the discrete logarithm problem.

   Edwards curves provide a number of implementation benefits for
   cryptography.  These benefits include formulas for curve operations
   that are among the fastest currently known, and for which the
   addition formulas are complete with no exceptional points.  However,
   the group of points on the curve is not of prime order, i.e., it has
   a cofactor larger than 1.  This abstraction mismatch is usually
   handled, if it is handled at all, by means of ad hoc protocol tweaks
   such as multiplying by the cofactor in an appropriate place.

   Even for simple protocols such as signatures, these tweaks can cause
   subtle issues.  For instance, Ed25519 implementations may have
   different validation behavior between batched and singleton
   verification, and at least as specified in [RFC8032], the set of
   valid signatures is not defined precisely [Ed25519ValidCrit].

   For more complex protocols, careful analysis is required as the
   original security proofs may no longer apply, and the tweaks for one
   protocol may have disastrous effects when applied to another (for
   instance, the octuple-spend vulnerability described in [MoneroVuln]).

   Decaf and Ristretto fix this abstraction mismatch in one place for
   all protocols, providing an abstraction to protocol implementors that
   matches the abstraction commonly assumed in protocol specifications
   while still allowing the use of high-performance curve
   implementations internally.  The abstraction layer imposes minor
   overhead but only in the encoding and decoding phases.

   While Ristretto is a general method and can be used in conjunction
   with any Edwards curve with cofactor 4 or 8, this document specifies
   the ristretto255 group, which can be implemented using Curve25519,
   and the decaf448 group, which can be implemented using edwards448.

   There are other elliptic curves that can be used internally to
   implement ristretto255 or decaf448; those implementations would be
   interoperable with one based on Curve25519 or edwards448, but those
   constructions are out of scope for this document.

   The Ristretto construction is described and justified in detail at
   [RistrettoGroup].

   This document represents the consensus of the Crypto Forum Research
   Group (CFRG).  This document is not an IETF product and is not a
   standard.

2.  Notation and Conventions Used in This Document

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
   "OPTIONAL" in this document are to be interpreted as described in BCP
   14 [RFC2119] [RFC8174] when, and only when, they appear in all
   capitals, as shown here.

   Readers are cautioned that the term "Curve25519" has varying
   interpretations in the literature and that the canonical meaning of
   the term has shifted over time.  Originally, it referred to a
   specific Diffie-Hellman key exchange mechanism.  Use shifted over
   time, and "Curve25519" has been used to refer to the abstract
   underlying curve, its concrete representation in Montgomery form, or
   the specific Diffie-Hellman mechanism.  This document uses the term
   "Curve25519" to refer to the abstract underlying curve, as
   recommended in [Naming].  The abstract Edwards form of the curve we
   refer to here as "Curve25519" is referred to in [RFC7748] as
   "edwards25519", and the Montgomery form that is isogenous to the
   Edwards form is referred to in [RFC7748] as "curve25519".

   Elliptic curve points in this document are represented in extended
   Edwards coordinates in the (x, y, z, t) format [Twisted], also called
   extended homogeneous coordinates in Section 5.1.4 of [RFC8032].
   Field elements are values modulo p, the Curve25519 prime 2^255 - 19
   or the edwards448 prime 2^448 - 2^224 - 1, as specified in Sections
   4.1 and 4.2 of [RFC7748], respectively.  All formulas specify field
   operations unless otherwise noted.  The symbol ^ denotes
   exponentiation.

   The | symbol represents a constant-time logical OR.

   The notation array[A:B] means the elements of array from A to B-1.
   That is, it is exclusive of B.  Arrays are indexed starting from 0.

   A byte is an 8-bit entity (also known as "octet"), and a byte string
   is an ordered sequence of bytes.  An N-byte string is a byte string
   of N bytes in length.

   Element encodings are presented as hex-encoded byte strings with
   whitespace added for readability.

2.1.  Negative Field Elements

   As in [RFC8032], given a field element e, define IS_NEGATIVE(e) as
   TRUE if the least nonnegative integer representing e is odd and FALSE
   if it is even.  This SHOULD be implemented in constant time.

2.2.  Constant-Time Operations

   We assume that the field element implementation supports the
   following operations, which SHOULD be implemented in constant time:

   *  CT_EQ(u, v): return TRUE if u = v, FALSE otherwise.
   *  CT_SELECT(v IF cond ELSE u): return v if cond is TRUE, else return
      u.
   *  CT_ABS(u): return -u if IS_NEGATIVE(u), else return u.

   Note that CT_ABS MAY be implemented as:

   CT_SELECT(-u IF IS_NEGATIVE(u) ELSE u)

3.  The Group Abstraction

   Ristretto and Decaf implement an abstract prime-order group interface
   that exposes only the behavior that is useful to higher-level
   protocols, without leaking curve-related details and pitfalls.

   Each abstract group exposes operations on abstract element and
   abstract scalar types.  The operations defined on these types
   include: decoding, encoding, equality, addition, negation,
   subtraction, and (multi-)scalar multiplication.  Each abstract group
   also exposes a deterministic function to derive abstract elements
   from fixed-length byte strings.  A description of each of these
   operations is below.

   Decoding is a function from byte strings to abstract elements with
   built-in validation, so that only the canonical encodings of valid
   elements are accepted.  The built-in validation avoids the need for
   explicit invalid curve checks.

   Encoding is a function from abstract elements to byte strings.
   Internally, an abstract element might have more than one possible
   representation; for example, the implementation might use projective
   coordinates.  When encoding, all equivalent representations of the
   same element are encoded as identical byte strings.  Decoding the
   output of the encoding function always succeeds and returns an
   element equivalent to the encoding input.

   The equality check reports whether two representations of an abstract
   element are equivalent.

   The element derivation function maps deterministically from byte
   strings of a fixed length to abstract elements.  It has two important
   properties.  First, if the input is a uniformly random byte string,
   then the output is (within a negligible statistical distance of) a
   uniformly random abstract group element.  This means the function is
   suitable for selecting random group elements.

   Second, although the element derivation function is many-to-one and
   therefore not strictly invertible, it is not pre-image resistant.  On
   the contrary, given an arbitrary abstract group element P, there is
   an efficient algorithm to randomly sample from byte strings that map
   to P.  In some contexts, this property would be a weakness, but it is
   important in some contexts: in particular, it means that a
   combination of a cryptographic hash function and the element
   derivation function is suitable to define encoding functions such as
   hash_to_ristretto255 (Appendix B of [RFC9380]) and hash_to_decaf448
   (Appendix C of [RFC9380]).

   Addition is the group operation.  The group has an identity element
   and prime order l.  Adding together l copies of the same element
   gives the identity.  Adding the identity element to any element
   returns that element unchanged.  Negation returns an element that,
   when added to the negation input, gives the identity element.
   Subtraction is the addition of a negated element, and scalar
   multiplication is the repeated addition of an element.

4.  ristretto255

   ristretto255 is an instantiation of the abstract prime-order group
   interface defined in Section 3.  This document describes how to
   implement the ristretto255 prime-order group using Curve25519 points
   as internal representations.

   A "ristretto255 group element" is the abstract element of the prime-
   order group.  An "element encoding" is the unique reversible encoding
   of a group element.  An "internal representation" is a point on the
   curve used to implement ristretto255.  Each group element can have
   multiple equivalent internal representations.

   Encoding, decoding, equality, and the element derivation function are
   defined in Section 4.3.  Element addition, subtraction, negation, and
   scalar multiplication are implemented by applying the corresponding
   operations directly to the internal representation.

   The group order is the same as the order of the Curve25519 prime-
   order subgroup:

   l = 2^252 + 27742317777372353535851937790883648493

   Since ristretto255 is a prime-order group, every element except the
   identity is a generator.  However, for interoperability, a canonical
   generator is selected, which can be internally represented by the
   Curve25519 base point, enabling reuse of existing precomputation for
   scalar multiplication.  The encoding of this canonical generator, as
   produced by the function specified in Section 4.3.2, is:

 e2f2ae0a 6abc4e71 a884a961 c500515f 58e30b6a a582dd8d b6a65945 e08d2d76

4.1.  Implementation Constants

   This document references the following constant field element values
   that are used for the implementation of group operations.

   *  D = 37095705934669439343138083508754565189542113879843219016388785
      533085940283555
      -  This is the Edwards d parameter for Curve25519, as specified in
         Section 4.1 of [RFC7748].
   *  SQRT_M1 = 19681161376707505956807079304988542015446066515923890162
      744021073123829784752
   *  SQRT_AD_MINUS_ONE = 2506306895338462347411141415870215270124453150
      2492656460079210482610430750235
   *  INVSQRT_A_MINUS_D = 5446930700890931692099581386874514160539359729
      2927456921205312896311721017578
   *  ONE_MINUS_D_SQ = 1159843021668779879193775521855586647937357759715
      417654439879720876111806838
   *  D_MINUS_ONE_SQ = 4044083434630853685810104246932319082624839914623
      8708352240133220865137265952

4.2.  Square Root of a Ratio of Field Elements

   The following function is defined on field elements and is used to
   implement other ristretto255 functions.  This function is only used
   internally to implement some of the group operations.

   On input field elements u and v, the function SQRT_RATIO_M1(u, v)
   returns:

   *  (TRUE, +sqrt(u/v)) if u and v are nonzero and u/v is square in the
      field;
   *  (TRUE, zero) if u is zero;
   *  (FALSE, zero) if v is zero and u is nonzero; and
   *  (FALSE, +sqrt(SQRT_M1*(u/v))) if u and v are nonzero and u/v is
      non-square in the field (so SQRT_M1*(u/v) is square in the field),

   where +sqrt(x) indicates the nonnegative square root of x in the
   field.

   The computation is similar to what is described in Section 5.1.3 of
   [RFC8032], with the difference that, if the input is non-square, the
   function returns a result with a defined relationship to the inputs.
   This result is used for efficient implementation of the derivation
   function.  The function can be refactored from an existing Ed25519
   implementation.

   SQRT_RATIO_M1(u, v) is defined as follows:

r = (u * v^3) * (u * v^7)^((p-5)/8) // Note: (p - 5) / 8 is an integer.
check = v * r^2

correct_sign_sqrt   = CT_EQ(check,          u)
flipped_sign_sqrt   = CT_EQ(check,         -u)
flipped_sign_sqrt_i = CT_EQ(check, -u*SQRT_M1)

r_prime = SQRT_M1 * r
r = CT_SELECT(r_prime IF flipped_sign_sqrt | flipped_sign_sqrt_i ELSE r)

// Choose the nonnegative square root.
r = CT_ABS(r)

was_square = correct_sign_sqrt | flipped_sign_sqrt

return (was_square, r)

4.3.  ristretto255 Group Operations

   This section describes the implementation of the external functions
   exposed by the ristretto255 prime-order group.

4.3.1.  Decode

   All elements are encoded as 32-byte strings.  Decoding proceeds as
   follows:

   1.  Interpret the string as an unsigned integer s in little-endian
       representation.  If the length of the string is not 32 bytes or
       if the resulting value is >= p, decoding fails.

      |  Note: Unlike the field element decoding described in [RFC7748],
      |  the most significant bit is not masked, and non-canonical
      |  values are rejected.  The test vectors in Appendix A.2 exercise
      |  these edge cases.

   2.  If IS_NEGATIVE(s) returns TRUE, decoding fails.
   3.  Process s as follows:

   ss = s^2
   u1 = 1 - ss
   u2 = 1 + ss
   u2_sqr = u2^2

   v = -(D * u1^2) - u2_sqr

   (was_square, invsqrt) = SQRT_RATIO_M1(1, v * u2_sqr)

   den_x = invsqrt * u2
   den_y = invsqrt * den_x * v

   x = CT_ABS(2 * s * den_x)
   y = u1 * den_y
   t = x * y

   4.  If was_square is FALSE, IS_NEGATIVE(t) returns TRUE, or y = 0,
       decoding fails.  Otherwise, return the group element represented
       by the internal representation (x, y, 1, t) as the result of
       decoding.

4.3.2.  Encode

   A group element with internal representation (x0, y0, z0, t0) is
   encoded as follows:

   1.  Process the internal representation into a field element s as
       follows:

   u1 = (z0 + y0) * (z0 - y0)
   u2 = x0 * y0

   // Ignore was_square since this is always square.
   (_, invsqrt) = SQRT_RATIO_M1(1, u1 * u2^2)

   den1 = invsqrt * u1
   den2 = invsqrt * u2
   z_inv = den1 * den2 * t0

   ix0 = x0 * SQRT_M1
   iy0 = y0 * SQRT_M1
   enchanted_denominator = den1 * INVSQRT_A_MINUS_D

   rotate = IS_NEGATIVE(t0 * z_inv)

   // Conditionally rotate x and y.
   x = CT_SELECT(iy0 IF rotate ELSE x0)
   y = CT_SELECT(ix0 IF rotate ELSE y0)
   z = z0
   den_inv = CT_SELECT(enchanted_denominator IF rotate ELSE den2)

   y = CT_SELECT(-y IF IS_NEGATIVE(x * z_inv) ELSE y)

   s = CT_ABS(den_inv * (z - y))

   2.  Return the 32-byte little-endian encoding of s.  More
       specifically, this is the encoding of the canonical
       representation of s as an integer between 0 and p-1, inclusive.

   Note that decoding and then re-encoding a valid group element will
   yield an identical byte string.

4.3.3.  Equals

   The equality function returns TRUE when two internal representations
   correspond to the same group element.  Note that internal
   representations MUST NOT be compared in any way other than specified
   here.

   For two internal representations (x1, y1, z1, t1) and (x2, y2, z2,
   t2), if

   CT_EQ(x1 * y2, y1 * x2) | CT_EQ(y1 * y2, x1 * x2)

   evaluates to TRUE, then return TRUE.  Otherwise, return FALSE.

   Note that the equality function always returns TRUE when applied to
   an internal representation and to the internal representation
   obtained by encoding and then re-decoding it.  However, the internal
   representations themselves might not be identical.

   Implementations MAY also perform constant-time byte comparisons on
   the encodings of group elements (produced by Section 4.3.2) for an
   equivalent, although less efficient, result.

4.3.4.  Element Derivation

   The element derivation function operates on 64-byte strings.  To
   obtain such an input from an arbitrary-length byte string,
   applications should use a domain-separated hash construction, the
   choice of which is out of scope for this document.

   The element derivation function on an input string b proceeds as
   follows:

   1.  Compute P1 as MAP(b[0:32]).
   2.  Compute P2 as MAP(b[32:64]).
   3.  Return P1 + P2.

   The MAP function is defined on 32-byte strings as:

   1.  Mask the most significant bit in the final byte of the string,
       and interpret the string as an unsigned integer r in little-
       endian representation.  Reduce r modulo p to obtain a field
       element t.
       *  Masking the most significant bit is equivalent to interpreting
          the whole string as an unsigned integer in little-endian
          representation and then reducing it modulo 2^255.

      |  Note: Similar to the field element decoding described in
      |  [RFC7748], and unlike the field element decoding described in
      |  Section 4.3.1, the most significant bit is masked, and non-
      |  canonical values are accepted.

   2.  Process t as follows:

   r = SQRT_M1 * t^2
   u = (r + 1) * ONE_MINUS_D_SQ
   v = (-1 - r*D) * (r + D)

   (was_square, s) = SQRT_RATIO_M1(u, v)
   s_prime = -CT_ABS(s*t)
   s = CT_SELECT(s IF was_square ELSE s_prime)
   c = CT_SELECT(-1 IF was_square ELSE r)

   N = c * (r - 1) * D_MINUS_ONE_SQ - v

   w0 = 2 * s * v
   w1 = N * SQRT_AD_MINUS_ONE
   w2 = 1 - s^2
   w3 = 1 + s^2

   3.  Return the group element represented by the internal
       representation (w0*w3, w2*w1, w1*w3, w0*w2).

4.4.  Scalar Field

   The scalars for the ristretto255 group are integers modulo the order
   l of the ristretto255 group.  Note that this is the same scalar field
   as Curve25519, allowing existing implementations to be reused.

   Scalars are encoded as 32-byte strings in little-endian order.
   Implementations SHOULD check that any scalar s falls in the range 0
   <= s < l when parsing them and reject non-canonical scalar encodings.
   Implementations SHOULD reduce scalars modulo l when encoding them as
   byte strings.  Omitting these strict range checks is NOT RECOMMENDED
   but is allowed to enable reuse of scalar arithmetic implementations
   in existing Curve25519 libraries.

   Given a uniformly distributed 64-byte string b, implementations can
   obtain a uniformly distributed scalar by interpreting the 64-byte
   string as a 512-bit unsigned integer in little-endian order and
   reducing the integer modulo l, as in [RFC8032].  To obtain such an
   input from an arbitrary-length byte string, applications should use a
   domain-separated hash construction, the choice of which is out of
   scope for this document.

5.  decaf448

   decaf448 is an instantiation of the abstract prime-order group
   interface defined in Section 3.  This document describes how to
   implement the decaf448 prime-order group using edwards448 points as
   internal representations.

   A "decaf448 group element" is the abstract element of the prime-order
   group.  An "element encoding" is the unique reversible encoding of a
   group element.  An "internal representation" is a point on the curve
   used to implement decaf448.  Each group element can have multiple
   equivalent internal representations.

   Encoding, decoding, equality, and the element derivation functions
   are defined in Section 5.3.  Element addition, subtraction, negation,
   and scalar multiplication are implemented by applying the
   corresponding operations directly to the internal representation.

   The group order is the same as the order of the edwards448 prime-
   order subgroup:

  l = 2^446 -
    13818066809895115352007386748515426880336692474882178609894547503885

   Since decaf448 is a prime-order group, every element except the
   identity is a generator; however, for interoperability, a canonical
   generator is selected.  This generator can be internally represented
   by 2*B, where B is the edwards448 base point, enabling reuse of
   existing precomputation for scalar multiplication.  The encoding of
   this canonical generator, as produced by the function specified in
   Section 5.3.2, is:

   66666666 66666666 66666666 66666666 66666666 66666666 66666666
   33333333 33333333 33333333 33333333 33333333 33333333 33333333

   This repetitive constant is equal to 1/sqrt(5) in decaf448's field,
   corresponding to the curve448 base point with x = 5.

5.1.  Implementation Constants

   This document references the following constant field element values
   that are used for the implementation of group operations.

   *  D = 72683872429560689054932380788800453435364136068731806028149019
      918061232816673077268639638369867654593008888446184363736105349801
      8326358
      -  This is the Edwards d parameter for edwards448, as specified in
         Section 4.2 of [RFC7748], and is equal to -39081 in the field.
   *  ONE_MINUS_D = 39082
   *  ONE_MINUS_TWO_D = 78163
   *  SQRT_MINUS_D = 989442336477322197691770048769290191284175762955299
      010740998895980437021160012578568021315638965153739277122320928458
      83226922417596214
   *  INVSQRT_MINUS_D = 315019913931389607337177038330951043522456072897
      266928557328499619017160722351061360252776265186336876723201881398
      623946864393857820716

5.2.  Square Root of a Ratio of Field Elements

   The following function is defined on field elements and is used to
   implement other decaf448 functions.  This function is only used
   internally to implement some of the group operations.

   On input field elements u and v, the function SQRT_RATIO_M1(u, v)
   returns:

   *  (TRUE, +sqrt(u/v)) if u and v are nonzero and u/v is square in the
      field;
   *  (TRUE, zero) if u is zero;
   *  (FALSE, zero) if v is zero and u is nonzero; and
   *  (FALSE, +sqrt(-u/v)) if u and v are nonzero and u/v is non-square
      in the field (so -(u/v) is square in the field),

   where +sqrt(x) indicates the nonnegative square root of x in the
   field.

   The computation is similar to what is described in Section 5.2.3 of
   [RFC8032], with the difference that, if the input is non-square, the
   function returns a result with a defined relationship to the inputs.
   This result is used for efficient implementation of the derivation
   function.  The function can be refactored from an existing edwards448
   implementation.

   SQRT_RATIO_M1(u, v) is defined as follows:

   r = u * (u * v)^((p - 3) / 4) // Note: (p - 3) / 4 is an integer.

   check = v * r^2
   was_square = CT_EQ(check, u)

   // Choose the nonnegative square root.
   r = CT_ABS(r)

   return (was_square, r)

5.3.  decaf448 Group Operations

   This section describes the implementation of the external functions
   exposed by the decaf448 prime-order group.

5.3.1.  Decode

   All elements are encoded as 56-byte strings.  Decoding proceeds as
   follows:

   1.  Interpret the string as an unsigned integer s in little-endian
       representation.  If the length of the string is not 56 bytes or
       if the resulting value is >= p, decoding fails.

      |  Note: Unlike the field element decoding described in [RFC7748],
      |  non-canonical values are rejected.  The test vectors in
      |  Appendix B.2 exercise these edge cases.

   2.  If IS_NEGATIVE(s) returns TRUE, decoding fails.
   3.  Process s as follows:

   ss = s^2
   u1 = 1 + ss

   u2 = u1^2 - 4 * D * ss

   (was_square, invsqrt) = SQRT_RATIO_M1(1, u2 * u1^2)

   u3 = CT_ABS(2 * s * invsqrt * u1 * SQRT_MINUS_D)

   x = u3 * invsqrt * u2 * INVSQRT_MINUS_D
   y = (1 - ss) * invsqrt * u1
   t = x * y

   4.  If was_square is FALSE, then decoding fails.  Otherwise, return
       the group element represented by the internal representation (x,
       y, 1, t) as the result of decoding.

5.3.2.  Encode

   A group element with internal representation (x0, y0, z0, t0) is
   encoded as follows:

   1.  Process the internal representation into a field element s as
       follows:

   u1 = (x0 + t0) * (x0 - t0)

   // Ignore was_square since this is always square.
   (_, invsqrt) = SQRT_RATIO_M1(1, u1 * ONE_MINUS_D * x0^2)

   ratio = CT_ABS(invsqrt * u1 * SQRT_MINUS_D)
   u2 = INVSQRT_MINUS_D * ratio * z0 - t0
   s = CT_ABS(ONE_MINUS_D * invsqrt * x0 * u2)

   2.  Return the 56-byte little-endian encoding of s.  More
       specifically, this is the encoding of the canonical
       representation of s as an integer between 0 and p-1, inclusive.

   Note that decoding and then re-encoding a valid group element will
   yield an identical byte string.

5.3.3.  Equals

   The equality function returns TRUE when two internal representations
   correspond to the same group element.  Note that internal
   representations MUST NOT be compared in any way other than specified
   here.

   For two internal representations (x1, y1, z1, t1) and (x2, y2, z2,
   t2), if

   CT_EQ(x1 * y2, y1 * x2)

   evaluates to TRUE, then return TRUE.  Otherwise, return FALSE.

   Note that the equality function always returns TRUE when applied to
   an internal representation and to the internal representation
   obtained by encoding and then re-decoding it.  However, the internal
   representations themselves might not be identical.

   Implementations MAY also perform constant-time byte comparisons on
   the encodings of group elements (produced by Section 5.3.2) for an
   equivalent, although less efficient, result.

5.3.4.  Element Derivation

   The element derivation function operates on 112-byte strings.  To
   obtain such an input from an arbitrary-length byte string,
   applications should use a domain-separated hash construction, the
   choice of which is out of scope for this document.

   The element derivation function on an input string b proceeds as
   follows:

   1.  Compute P1 as MAP(b[0:56]).
   2.  Compute P2 as MAP(b[56:112]).
   3.  Return P1 + P2.

   The MAP function is defined on 56-byte strings as:

   1.  Interpret the string as an unsigned integer r in little-endian
       representation.  Reduce r modulo p to obtain a field element t.

      |  Note: Similar to the field element decoding described in
      |  [RFC7748], and unlike the field element decoding described in
      |  Section 5.3.1, non-canonical values are accepted.

   2.  Process t as follows:

   r = -t^2
   u0 = d * (r-1)
   u1 = (u0 + 1) * (u0 - r)

   (was_square, v) = SQRT_RATIO_M1(ONE_MINUS_TWO_D, (r + 1) * u1)
   v_prime = CT_SELECT(v IF was_square ELSE t * v)
   sgn     = CT_SELECT(1 IF was_square ELSE -1)
   s = v_prime * (r + 1)

   w0 = 2 * CT_ABS(s)
   w1 = s^2 + 1
   w2 = s^2 - 1
   w3 = v_prime * s * (r - 1) * ONE_MINUS_TWO_D + sgn

   3.  Return the group element represented by the internal
       representation (w0*w3, w2*w1, w1*w3, w0*w2).

5.4.  Scalar Field

   The scalars for the decaf448 group are integers modulo the order l of
   the decaf448 group.  Note that this is the same scalar field as
   edwards448, allowing existing implementations to be reused.

   Scalars are encoded as 56-byte strings in little-endian order.
   Implementations SHOULD check that any scalar s falls in the range 0
   <= s < l when parsing them and reject non-canonical scalar encodings.
   Implementations SHOULD reduce scalars modulo l when encoding them as
   byte strings.  Omitting these strict range checks is NOT RECOMMENDED
   but is allowed to enable reuse of scalar arithmetic implementations
   in existing edwards448 libraries.

   Given a uniformly distributed 64-byte string b, implementations can
   obtain a uniformly distributed scalar by interpreting the 64-byte
   string as a 512-bit unsigned integer in little-endian order and
   reducing the integer modulo l.  To obtain such an input from an
   arbitrary-length byte string, applications should use a domain-
   separated hash construction, the choice of which is out of scope for
   this document.

6.  API Considerations

   ristretto255 and decaf448 are abstractions that implement two prime-
   order groups.  Their elements are represented by curve points, but
   are not curve points, and implementations SHOULD reflect that fact.
   That is, the type representing an element of the group SHOULD be
   opaque to the caller, meaning they do not expose the underlying curve
   point or field elements.  Moreover, implementations SHOULD NOT expose
   any internal constants or functions used in the implementation of the
   group operations.

   The reason for this encapsulation is that ristretto255 and decaf448
   implementations can change their underlying curve without causing any
   breaking change.  The ristretto255 and decaf448 constructions are
   carefully designed so that this will be the case, as long as
   implementations do not expose internal representations or operate on
   them except as described in this document.  In particular,
   implementations SHOULD NOT define any external ristretto255 or
   decaf448 interface as operating on arbitrary curve points, and they
   SHOULD NOT construct group elements except via decoding, the element
   derivation function, or group operations on other valid group
   elements per Section 3.  However, they are allowed to apply any
   optimization strategy to the internal representations as long as it
   doesn't change the exposed behavior of the API.

   It is RECOMMENDED that implementations not perform a decoding and
   encoding operation for each group operation, as it is inefficient and
   unnecessary.  Implementations SHOULD instead provide an opaque type
   to hold the internal representation through multiple operations.

7.  IANA Considerations

   This document has no IANA actions.

8.  Security Considerations

   The ristretto255 and decaf448 groups provide higher-level protocols
   with the abstraction they expect: a prime-order group.  Therefore,
   it's expected to be safer for use in any situation where Curve25519
   or edwards448 is used to implement a protocol requiring a prime-order
   group.  Note that the safety of the abstraction can be defeated by
   implementations that do not follow the guidance in Section 6.

   There is no function to test whether an elliptic curve point is a
   valid internal representation of a group element.  The decoding
   function always returns a valid internal representation or an error,
   and operations exposed by the group per Section 3 return valid
   internal representations when applied to valid internal
   representations.  In this way, an implementation can maintain the
   invariant that an internal representation is always valid, so that
   checking is never necessary, and invalid states are unrepresentable.

9.  References

9.1.  Normative References

   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
              Requirement Levels", BCP 14, RFC 2119,
              DOI 10.17487/RFC2119, March 1997,
              <https://www.rfc-editor.org/info/rfc2119>.

   [RFC8174]  Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
              2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
              May 2017, <https://www.rfc-editor.org/info/rfc8174>.

9.2.  Informative References

   [Decaf]    Hamburg, M., "Decaf: Eliminating cofactors through point
              compression", 2015,
              <https://www.shiftleft.org/papers/decaf/decaf.pdf>.

   [Ed25519ValidCrit]
              de Valence, H., "It's 255:19AM. Do you know what your
              validation criteria are?", 4 October 2020,
              <https://hdevalence.ca/blog/2020-10-04-its-25519am>.

   [MoneroVuln]
              Nick, J., "Exploiting Low Order Generators in One-Time
              Ring Signatures", May 2017,
              <https://jonasnick.github.io/blog/2017/05/23/exploiting-
              low-order-generators-in-one-time-ring-signatures/>.

   [Naming]   Bernstein, D. J., "Subject: [Cfrg] 25519 naming", message
              to the Cfrg mailing list, 26 August 2014,
              <https://mailarchive.ietf.org/arch/msg/cfrg/-
              9LEdnzVrE5RORux3Oo_oDDRksU/>.

   [RFC7748]  Langley, A., Hamburg, M., and S. Turner, "Elliptic Curves
              for Security", RFC 7748, DOI 10.17487/RFC7748, January
              2016, <https://www.rfc-editor.org/info/rfc7748>.

   [RFC8032]  Josefsson, S. and I. Liusvaara, "Edwards-Curve Digital
              Signature Algorithm (EdDSA)", RFC 8032,
              DOI 10.17487/RFC8032, January 2017,
              <https://www.rfc-editor.org/info/rfc8032>.

   [RFC9380]  Faz-Hernandez, A., Scott, S., Sullivan, N., Wahby, R. S.,
              and C. A. Wood, "Hashing to Elliptic Curves", RFC 9380,
              DOI 10.17487/RFC9380, August 2023,
              <https://www.rfc-editor.org/info/rfc9380>.

   [RistrettoGroup]
              de Valence, H., Lovecruft, I., Arcieri, T., and M.
              Hamburg, "The Ristretto Group", <https://ristretto.group>.

   [Twisted]  Hisil, H., Wong, K. K., Carter, G., and E. Dawson,
              "Twisted Edwards Curves Revisited", Cryptology ePrint
              Archive, Paper 2008/522, December 2008,
              <https://eprint.iacr.org/2008/522>.

Appendix A.  Test Vectors for ristretto255

   This section contains test vectors for ristretto255.  The octets are
   hex encoded, and whitespace is inserted for readability.

A.1.  Multiples of the Generator

   The following are the encodings of the multiples 0 to 15 of the
   canonical generator, represented as an array of elements.  That is,
   the first entry is the encoding of the identity element, and each
   successive entry is obtained by adding the generator to the previous
   entry.

   B[ 0]: 00000000 00000000 00000000 00000000 00000000 00000000 00000000
          00000000
   B[ 1]: e2f2ae0a 6abc4e71 a884a961 c500515f 58e30b6a a582dd8d b6a65945
          e08d2d76
   B[ 2]: 6a493210 f7499cd1 7fecb510 ae0cea23 a110e8d5 b901f8ac add3095c
          73a3b919
   B[ 3]: 94741f5d 5d52755e ce4f23f0 44ee27d5 d1ea1e2b d196b462 166b1615
          2a9d0259
   B[ 4]: da808627 73358b46 6ffadfe0 b3293ab3 d9fd53c5 ea6c9553 58f56832
          2daf6a57
   B[ 5]: e882b131 016b52c1 d3337080 187cf768 423efccb b517bb49 5ab812c4
          160ff44e
   B[ 6]: f64746d3 c92b1305 0ed8d802 36a7f000 7c3b3f96 2f5ba793 d19a601e
          bb1df403
   B[ 7]: 44f53520 926ec81f bd5a3878 45beb7df 85a96a24 ece18738 bdcfa6a7
          822a176d
   B[ 8]: 903293d8 f2287ebe 10e2374d c1a53e0b c887e592 699f02d0 77d5263c
          dd55601c
   B[ 9]: 02622ace 8f7303a3 1cafc63f 8fc48fdc 16e1c8c8 d234b2f0 d6685282
          a9076031
   B[10]: 20706fd7 88b2720a 1ed2a5da d4952b01 f413bcf0 e7564de8 cdc81668
          9e2db95f
   B[11]: bce83f8b a5dd2fa5 72864c24 ba1810f9 522bc600 4afe9587 7ac73241
          cafdab42
   B[12]: e4549ee1 6b9aa030 99ca208c 67adafca fa4c3f3e 4e5303de 6026e3ca
          8ff84460
   B[13]: aa52e000 df2e16f5 5fb1032f c33bc427 42dad6bd 5a8fc0be 0167436c
          5948501f
   B[14]: 46376b80 f409b29d c2b5f6f0 c5259199 0896e571 6f41477c d30085ab
          7f10301e
   B[15]: e0c418f7 c8d9c4cd d7395b93 ea124f3a d99021bb 681dfc33 02a9d99a
          2e53e64e

   Note that because

   B[i+1] = B[i] + B[1]

   these test vectors allow testing of the encoding function and the
   implementation of addition simultaneously.

A.2.  Invalid Encodings

   These are examples of encodings that MUST be rejected according to
   Section 4.3.1.

   # Non-canonical field encodings.
   00ffffff ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff
   ffffffff

   ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff
   ffffff7f

   f3ffffff ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff
   ffffff7f

   edffffff ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff
   ffffff7f

   # Negative field elements.
   01000000 00000000 00000000 00000000 00000000 00000000 00000000
   00000000

   01ffffff ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff
   ffffff7f

   ed57ffd8 c914fb20 1471d1c3 d245ce3c 746fcbe6 3a3679d5 1b6a516e
   bebe0e20

   c34c4e18 26e5d403 b78e246e 88aa051c 36ccf0aa febffe13 7d148a2b
   f9104562

   c940e5a4 404157cf b1628b10 8db051a8 d439e1a4 21394ec4 ebccb9ec
   92a8ac78

   47cfc549 7c53dc8e 61c91d17 fd626ffb 1c49e2bc a94eed05 2281b510
   b1117a24

   f1c6165d 33367351 b0da8f6e 4511010c 68174a03 b6581212 c71c0e1d
   026c3c72

   87260f7a 2f124951 18360f02 c26a470f 450dadf3 4a413d21 042b43b9
   d93e1309

   # Non-square x^2.
   26948d35 ca62e643 e26a8317 7332e6b6 afeb9d08 e4268b65 0f1f5bbd
   8d81d371

   4eac077a 713c57b4 f4397629 a4145982 c661f480 44dd3f96 427d40b1
   47d9742f

   de6a7b00 deadc788 eb6b6c8d 20c0ae96 c2f20190 78fa604f ee5b87d6
   e989ad7b

   bcab477b e20861e0 1e4a0e29 5284146a 510150d9 817763ca f1a6f4b4
   22d67042

   2a292df7 e32cabab bd9de088 d1d1abec 9fc0440f 637ed2fb a145094d
   c14bea08

   f4a9e534 fc0d216c 44b218fa 0c42d996 35a0127e e2e53c71 2f706096
   49fdff22

   8268436f 8c412619 6cf64b3c 7ddbda90 746a3786 25f9813d d9b84570
   77256731

   2810e5cb c2cc4d4e ece54f61 c6f69758 e289aa7a b440b3cb eaa21995
   c2f4232b

   # Negative x * y value.
   3eb858e7 8f5a7254 d8c97311 74a94f76 755fd394 1c0ac937 35c07ba1
   4579630e

   a45fdc55 c76448c0 49a1ab33 f17023ed fb2be358 1e9c7aad e8a61252
   15e04220

   d483fe81 3c6ba647 ebbfd3ec 41adca1c 6130c2be eee9d9bf 065c8d15
   1c5f396e

   8a2e1d30 050198c6 5a544831 23960ccc 38aef684 8e1ec8f5 f780e852
   3769ba32

   32888462 f8b486c6 8ad7dd96 10be5192 bbeaf3b4 43951ac1 a8118419
   d9fa097b

   22714250 1b9d4355 ccba2904 04bde415 75b03769 3cef1f43 8c47f8fb
   f35d1165

   5c37cc49 1da847cf eb9281d4 07efc41e 15144c87 6e0170b4 99a96a22
   ed31e01e

   44542511 7cb8c90e dcbc7c1c c0e74f74 7f2c1efa 5630a967 c64f2877
   92a48a4b

   # s = -1, which causes y = 0.
   ecffffff ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff
   ffffff7f

A.3.  Group Elements from Uniform Byte Strings

   The following pairs are inputs to the element derivation function of
   Section 4.3.4 and their encoded outputs.

   I: 5d1be09e3d0c82fc538112490e35701979d99e06ca3e2b5b54bffe8b4dc772c1
      4d98b696a1bbfb5ca32c436cc61c16563790306c79eaca7705668b47dffe5bb6
   O: 3066f82a 1a747d45 120d1740 f1435853 1a8f04bb ffe6a819 f86dfe50
      f44a0a46

   I: f116b34b8f17ceb56e8732a60d913dd10cce47a6d53bee9204be8b44f6678b27
      0102a56902e2488c46120e9276cfe54638286b9e4b3cdb470b542d46c2068d38
   O: f26e5b6f 7d362d2d 2a94c5d0 e7602cb4 773c95a2 e5c31a64 f133189f
      a76ed61b

   I: 8422e1bbdaab52938b81fd602effb6f89110e1e57208ad12d9ad767e2e25510c
      27140775f9337088b982d83d7fcf0b2fa1edffe51952cbe7365e95c86eaf325c
   O: 006ccd2a 9e6867e6 a2c5cea8 3d3302cc 9de128dd 2a9a57dd 8ee7b9d7
      ffe02826

   I: ac22415129b61427bf464e17baee8db65940c233b98afce8d17c57beeb7876c2
      150d15af1cb1fb824bbd14955f2b57d08d388aab431a391cfc33d5bafb5dbbaf
   O: f8f0c87c f237953c 5890aec3 99816900 5dae3eca 1fbb0454 8c635953
      c817f92a

   I: 165d697a1ef3d5cf3c38565beefcf88c0f282b8e7dbd28544c483432f1cec767
      5debea8ebb4e5fe7d6f6e5db15f15587ac4d4d4a1de7191e0c1ca6664abcc413
   O: ae81e7de df20a497 e10c304a 765c1767 a42d6e06 029758d2 d7e8ef7c
      c4c41179

   I: a836e6c9a9ca9f1e8d486273ad56a78c70cf18f0ce10abb1c7172ddd605d7fd2
      979854f47ae1ccf204a33102095b4200e5befc0465accc263175485f0e17ea5c
   O: e2705652 ff9f5e44 d3e841bf 1c251cf7 dddb77d1 40870d1a b2ed64f1
      a9ce8628

   I: 2cdc11eaeb95daf01189417cdddbf95952993aa9cb9c640eb5058d09702c7462
      2c9965a697a3b345ec24ee56335b556e677b30e6f90ac77d781064f866a3c982
   O: 80bd0726 2511cdde 4863f8a7 434cef69 6750681c b9510eea 557088f7
      6d9e5065

   The following element derivation function inputs all produce the same
   encoded output.

   I: edffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff
      1200000000000000000000000000000000000000000000000000000000000000
   I: edffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff7f
      ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff
   I: 0000000000000000000000000000000000000000000000000000000000000080
      ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff7f
   I: 0000000000000000000000000000000000000000000000000000000000000000
      1200000000000000000000000000000000000000000000000000000000000080

   O: 30428279 1023b731 28d277bd cb5c7746 ef2eac08 dde9f298 3379cb8e
      5ef0517f

A.4.  Square Root of a Ratio of Field Elements

   The following are inputs and outputs of SQRT_RATIO_M1(u, v) defined
   in Section 4.2.  The values are little-endian encodings of field
   elements.

   u: 0000000000000000000000000000000000000000000000000000000000000000
   v: 0000000000000000000000000000000000000000000000000000000000000000
   was_square: TRUE
   r: 0000000000000000000000000000000000000000000000000000000000000000

   u: 0000000000000000000000000000000000000000000000000000000000000000
   v: 0100000000000000000000000000000000000000000000000000000000000000
   was_square: TRUE
   r: 0000000000000000000000000000000000000000000000000000000000000000

   u: 0100000000000000000000000000000000000000000000000000000000000000
   v: 0000000000000000000000000000000000000000000000000000000000000000
   was_square: FALSE
   r: 0000000000000000000000000000000000000000000000000000000000000000

   u: 0200000000000000000000000000000000000000000000000000000000000000
   v: 0100000000000000000000000000000000000000000000000000000000000000
   was_square: FALSE
   r: 3c5ff1b5d8e4113b871bd052f9e7bcd0582804c266ffb2d4f4203eb07fdb7c54

   u: 0400000000000000000000000000000000000000000000000000000000000000
   v: 0100000000000000000000000000000000000000000000000000000000000000
   was_square: TRUE
   r: 0200000000000000000000000000000000000000000000000000000000000000

   u: 0100000000000000000000000000000000000000000000000000000000000000
   v: 0400000000000000000000000000000000000000000000000000000000000000
   was_square: TRUE
   r: f6ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff3f

Appendix B.  Test Vectors for decaf448

   This section contains test vectors for decaf448.  The octets are hex
   encoded, and whitespace is inserted for readability.

B.1.  Multiples of the Generator

   The following are the encodings of the multiples 0 to 15 of the
   canonical generator, represented as an array of elements.  That is,
   the first entry is the encoding of the identity element, and each
   successive entry is obtained by adding the generator to the previous
   entry.

   B[ 0]: 00000000 00000000 00000000 00000000 00000000 00000000 00000000
          00000000 00000000 00000000 00000000 00000000 00000000 00000000
   B[ 1]: 66666666 66666666 66666666 66666666 66666666 66666666 66666666
          33333333 33333333 33333333 33333333 33333333 33333333 33333333
   B[ 2]: c898eb4f 87f97c56 4c6fd61f c7e49689 314a1f81 8ec85eeb 3bd5514a
          c816d387 78f69ef3 47a89fca 817e66de fdedce17 8c7cc709 b2116e75
   B[ 3]: a0c09bf2 ba7208fd a0f4bfe3 d0f5b29a 54301230 6d43831b 5adc6fe7
          f8596fa3 08763db1 5468323b 11cf6e4a eb8c18fe 44678f44 545a69bc
   B[ 4]: b46f1836 aa287c0a 5a5653f0 ec5ef9e9 03f436e2 1c1570c2 9ad9e5f5
          96da97ee af17150a e30bcb31 74d04bc2 d712c8c7 789d7cb4 fda138f4
   B[ 5]: 1c5bbecf 4741dfaa e79db72d face00ea aac502c2 060934b6 eaaeca6a
          20bd3da9 e0be8777 f7d02033 d1b15884 232281a4 1fc7f80e ed04af5e
   B[ 6]: 86ff0182 d40f7f9e db786251 5821bd67 bfd6165a 3c44de95 d7df79b8
          779ccf64 60e3c68b 70c16aaa 280f2d7b 3f22d745 b97a8990 6cfc476c
   B[ 7]: 502bcb68 42eb06f0 e49032ba e87c554c 031d6d4d 2d7694ef bf9c468d
          48220c50 f8ca2884 3364d70c ee92d6fe 246e6144 8f9db980 8b3b2408
   B[ 8]: 0c9810f1 e2ebd389 caa78937 4d780079 74ef4d17 227316f4 0e578b33
          6827da3f 6b482a47 94eb6a39 75b971b5 e1388f52 e91ea2f1 bcb0f912
   B[ 9]: 20d41d85 a18d5657 a2964032 1563bbd0 4c2ffbd0 a37a7ba4 3a4f7d26
          3ce26faf 4e1f74f9 f4b590c6 9229ae57 1fe37fa6 39b5b8eb 48bd9a55
   B[10]: e6b4b8f4 08c7010d 0601e7ed a0c309a1 a42720d6 d06b5759 fdc4e1ef
          e22d076d 6c44d42f 508d67be 462914d2 8b8edce3 2e709430 5164af17
   B[11]: be88bbb8 6c59c13d 8e9d09ab 98105f69 c2d1dd13 4dbcd3b0 863658f5
          3159db64 c0e139d1 80f3c89b 8296d0ae 324419c0 6fa87fc7 daaf34c1
   B[12]: a456f936 9769e8f0 8902124a 0314c7a0 6537a06e 32411f4f 93415950
          a17badfa 7442b621 7434a3a0 5ef45be5 f10bd7b2 ef8ea00c 431edec5
   B[13]: 186e452c 4466aa43 83b4c002 10d52e79 22dbf977 1e8b47e2 29a9b7b7
          3c8d10fd 7ef0b6e4 1530f91f 24a3ed9a b71fa38b 98b2fe47 46d51d68
   B[14]: 4ae7fdca e9453f19 5a8ead5c be1a7b96 99673b52 c40ab279 27464887
          be53237f 7f3a21b9 38d40d0e c9e15b1d 5130b13f fed81373 a53e2b43
   B[15]: 841981c3 bfeec3f6 0cfeca75 d9d8dc17 f46cf010 6f2422b5 9aec580a
          58f34227 2e3a5e57 5a055ddb 051390c5 4c24c6ec b1e0aceb 075f6056

B.2.  Invalid Encodings

   These are examples of encodings that MUST be rejected according to
   Section 5.3.1.

   # Non-canonical field encodings.
   8e24f838 059ee9fe f1e20912 6defe53d cd74ef9b 6304601c 6966099e
   ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff

   86fcc721 2bd4a0b9 80928666 dc28c444 a605ef38 e09fb569 e28d4443
   ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff

   866d54bd 4c4ff41a 55d4eefd beca73cb d653c7bd 3135b383 708ec0bd
   ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff

   4a380ccd ab9c8636 4a89e77a 464d64f9 157538cf dfa686ad c0d5ece4
   ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff

   f22d9d4c 945dd44d 11e0b1d3 d3d358d9 59b4844d 83b08c44 e659d79f
   ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff

   8cdffc68 1aa99e9c 818c8ef4 c3808b58 e86acdef 1ab68c84 77af185b
   ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff

   0e1c12ac 7b5920ef fbd044e8 97c57634 e2d05b5c 27f8fa3d f8a086a1
   ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff ffffffff

   # Negative field elements.
   15141bd2 121837ef 71a0016b d11be757 507221c2 6542244f 23806f3f
   d3496b7d 4c368262 76f3bf5d eea2c60c 4fa4cec6 9946876d a497e795

   455d3802 38434ab7 40a56267 f4f46b7d 2eb2dd8e e905e51d 7b0ae8a6
   cb2bae50 1e67df34 ab21fa45 946068c9 f233939b 1d9521a9 98b7cb93

   810b1d8e 8bf3a9c0 23294bbf d3d905a9 7531709b dc0f4239 0feedd70
   10f77e98 686d400c 9c86ed25 0ceecd9d e0a18888 ffecda0f 4ea1c60d

   d3af9cc4 1be0e5de 83c0c627 3bedcb93 51970110 044a9a41 c7b9b226
   7cdb9d7b f4dc9c2f db8bed32 87818460 4f1d9944 305a8df4 274ce301

   9312bcab 09009e43 30ff89c4 bc1e9e00 0d863efc 3c863d3b 6c507a40
   fd2cdefd e1bf0892 b4b5ed97 80b91ed1 398fb4a7 344c605a a5efda74

   53d11bce 9e62a29d 63ed82ae 93761bdd 76e38c21 e2822d6e bee5eb1c
   5b8a03ea f9df749e 2490eda9 d8ac27d1 f71150de 93668074 d18d1c3a

   697c1aed 3cd88585 15d4be8a c158b229 fe184d79 cb2b06e4 9210a6f3
   a7cd537b cd9bd390 d96c4ab6 a4406da5 d9364072 6285370c fa95df80

   # Non-square x^2.
   58ad4871 5c9a1025 69b68b88 362a4b06 45781f5a 19eb7e59 c6a4686f
   d0f0750f f42e3d7a f1ab38c2 9d69b670 f3125891 9c9fdbf6 093d06c0

   8ca37ee2 b15693f0 6e910cf4 3c4e32f1 d5551dda 8b1e48cb 6ddd55e4
   40dbc7b2 96b60191 9a4e4069 f59239ca 247ff693 f7daa42f 086122b1

   982c0ec7 f43d9f97 c0a74b36 db0abd9c a6bfb981 23a90782 787242c8
   a523cdc7 6df14a91 0d544711 27e7662a 1059201f 902940cd 39d57af5

   baa9ab82 d07ca282 b968a911 a6c3728d 74bf2fe2 58901925 787f03ee
   4be7e3cb 6684fd1b cfe5071a 9a974ad2 49a4aaa8 ca812642 16c68574

   2ed9ffe2 ded67a37 2b181ac5 24996402 c4297062 9db03f5e 8636cbaf
   6074b523 d154a7a8 c4472c4c 353ab88c d6fec7da 7780834c c5bd5242

   f063769e 4241e76d 815800e4 933a3a14 4327a30e c40758ad 3723a788
   388399f7 b3f5d45b 6351eb8e ddefda7d 5bff4ee9 20d338a8 b89d8b63

   5a0104f1 f55d152c eb68bc13 81824998 91d90ee8 f09b4003 8ccc1e07
   cb621fd4 62f781d0 45732a4f 0bda73f0 b2acf943 55424ff0 388d4b9c

B.3.  Group Elements from Uniform Byte Strings

   The following pairs are inputs to the element derivation function of
   Section 5.3.4 and their encoded outputs.

   I: cbb8c991fd2f0b7e1913462d6463e4fd2ce4ccdd28274dc2ca1f4165
      d5ee6cdccea57be3416e166fd06718a31af45a2f8e987e301be59ae6
      673e963001dbbda80df47014a21a26d6c7eb4ebe0312aa6fffb8d1b2
      6bc62ca40ed51f8057a635a02c2b8c83f48fa6a2d70f58a1185902c0
   O: 0c709c96 07dbb01c 94513358 745b7c23 953d03b3 3e39c723 4e268d1d
      6e24f340 14ccbc22 16b965dd 231d5327 e591dc3c 0e8844cc fd568848

   I: b6d8da654b13c3101d6634a231569e6b85961c3f4b460a08ac4a5857
      069576b64428676584baa45b97701be6d0b0ba18ac28d443403b4569
      9ea0fbd1164f5893d39ad8f29e48e399aec5902508ea95e33bc1e9e4
      620489d684eb5c26bc1ad1e09aba61fabc2cdfee0b6b6862ffc8e55a
   O: 76ab794e 28ff1224 c727fa10 16bf7f1d 329260b7 218a39ae a2fdb17d
      8bd91190 17b093d6 41cedf74 328c3271 84dc6f2a 64bd90ed dccfcdab

   I: 36a69976c3e5d74e4904776993cbac27d10f25f5626dd45c51d15dcf
      7b3e6a5446a6649ec912a56895d6baa9dc395ce9e34b868d9fb2c1fc
      72eb6495702ea4f446c9b7a188a4e0826b1506b0747a6709f37988ff
      1aeb5e3788d5076ccbb01a4bc6623c92ff147a1e21b29cc3fdd0e0f4
   O: c8d7ac38 4143500e 50890a1c 25d64334 3accce58 4caf2544 f9249b2b
      f4a69210 82be0e7f 3669bb5e c24535e6 c45621e1 f6dec676 edd8b664

   I: d5938acbba432ecd5617c555a6a777734494f176259bff9dab844c81
      aadcf8f7abd1a9001d89c7008c1957272c1786a4293bb0ee7cb37cf3
      988e2513b14e1b75249a5343643d3c5e5545a0c1a2a4d3c685927c38
      bc5e5879d68745464e2589e000b31301f1dfb7471a4f1300d6fd0f99
   O: 62beffc6 b8ee11cc d79dbaac 8f0252c7 50eb052b 192f41ee ecb12f29
      79713b56 3caf7d22 588eca5e 80995241 ef963e7a d7cb7962 f343a973

   I: 4dec58199a35f531a5f0a9f71a53376d7b4bdd6bbd2904234a8ea65b
      bacbce2a542291378157a8f4be7b6a092672a34d85e473b26ccfbd4c
      dc6739783dc3f4f6ee3537b7aed81df898c7ea0ae89a15b5559596c2
      a5eeacf8b2b362f3db2940e3798b63203cae77c4683ebaed71533e51
   O: f4ccb31d 263731ab 88bed634 304956d2 603174c6 6da38742 053fa37d
      d902346c 3862155d 68db63be 87439e3d 68758ad7 268e239d 39c4fd3b

   I: df2aa1536abb4acab26efa538ce07fd7bca921b13e17bc5ebcba7d1b
      6b733deda1d04c220f6b5ab35c61b6bcb15808251cab909a01465b8a
      e3fc770850c66246d5a9eae9e2877e0826e2b8dc1bc08009590bc677
      8a84e919fbd28e02a0f9c49b48dc689eb5d5d922dc01469968ee81b5
   O: 7e79b00e 8e0a76a6 7c0040f6 2713b8b8 c6d6f05e 9c6d0259 2e8a22ea
      896f5dea cc7c7df5 ed42beae 6fedb900 0285b482 aa504e27 9fd49c32

   I: e9fb440282e07145f1f7f5ecf3c273212cd3d26b836b41b02f108431
      488e5e84bd15f2418b3d92a3380dd66a374645c2a995976a015632d3
      6a6c2189f202fc766e1c82f50ad9189be190a1f0e8f9b9e69c9c18cc
      98fdd885608f68bf0fdedd7b894081a63f70016a8abf04953affbefa
   O: 20b171cb 16be977f 15e013b9 752cf86c 54c631c4 fc8cbf7c 03c4d3ac
      9b8e8640 e7b0e930 0b987fe0 ab504466 9314f6ed 1650ae03 7db853f1

Acknowledgements

   The authors would like to thank Daira Emma Hopwood, Riad S. Wahby,
   Christopher Wood, and Thomas Pornin for their comments on the
   document.

Authors' Addresses

   Henry de Valence
   Email: ietf@hdevalence.ca

   Jack Grigg
   Email: ietf@jackgrigg.com

   Mike Hamburg
   Email: ietf@shiftleft.org

   Isis Lovecruft
   Email: ietf@en.ciph.re

   George Tankersley
   Email: ietf@gtank.cc

   Filippo Valsorda
   Email: ietf@filippo.io