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Replace BigInt based elliptic curve library #4027
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We should consider compile time configuration of which curves get instantiated (as pointed out here). Much like the compile-time configuration of having "kyber" and/or "kyber_90s", for instance. Adding one build module per curve should do the trick, and probably provides the best affordance for users. On the other hand, it produces quite a bit of boilerplate due to subdirectories, Alternatively, I could see this as a dedicated compile-time switch: Like:
and then simply |
The [*] I mean right now ECDSA etc still use BigInt, even after both #3979 and #4042 land. There are several more steps here until the whole thing hangs together. But in the end state, we'll have fast ECC for specific curves, plus fallback code for weird curves, application curves, etc. If you disable the fast curve, it doesn't disable the curve, just disables it going fast. That said there may be environments where the code size becomes an issue. I tried out a module per curve and it was not so bad. There are likely to not be more than ~5 new curves added here over time so I don't think it's an issue in an ongoing way. In the end we could consider also having a way of disabling the slowpath BigInt stuff, which would benefit environments that are using just P-256 or something. |
Nice! I saw that you split the curve into compile-time modules. Indeed the boilerplate isn't so bad. Also provides a nice place to keep curve-specific special cases. 👍 I added a few minor suggestions, in which the |
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027
For P-256 this speeds up projective->affine conversion by about 5%, saving ~2K cycles. For P-384 it speeds up conversion by 25%, saving 8K cycles. For P-521 it speeds up conversion by 20%, saving 33K cycles. GH #4027 The savings are most pronounced with ECDSA signing (since it is the fastest operation), improving by 2%, 4%, and 2% resp.
For P-256 this speeds up projective->affine conversion by about 5%, saving ~2K cycles. For P-384 it speeds up conversion by 25%, saving 8K cycles. For P-521 it speeds up conversion by 20%, saving 33K cycles. The savings are most pronounced with ECDSA signing (since it is the fastest operation), improving by 2%, 4%, and 2% resp. GH #4027
For P-256 this speeds up projective->affine conversion by about 5%, saving ~2K cycles. For P-384 it speeds up conversion by 25%, saving 8K cycles. For P-521 it speeds up conversion by 20%, saving 33K cycles. The savings are most pronounced with ECDSA signing (since it is the fastest operation), improving by 2%, 4%, and 2% resp. GH #4027
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027
For P-256 this speeds up projective->affine conversion by about 5%, saving ~2K cycles. For P-384 it speeds up conversion by 25%, saving 8K cycles. For P-521 it speeds up conversion by 20%, saving 33K cycles. The savings are most pronounced with ECDSA signing (since it is the fastest operation), improving by 2%, 4%, and 2% resp. GH #4027
For P-256 this speeds up projective->affine conversion by about 5%, saving ~2K cycles. For P-384 it speeds up conversion by 25%, saving 8K cycles. For P-521 it speeds up conversion by 20%, saving 33K cycles. The savings are most pronounced with ECDSA signing (since it is the fastest operation), improving by 2%, 4%, and 2% resp. GH #4027
This one is a little more involved since this is the first curve where p != 3 mod 4, and in fact since P-224 is == 1 mod 16 we must use Shanks-Tonelli GH #4027
This one is a little more involved since this is the first curve where p != 3 mod 4, and in fact since P-224 is == 1 mod 16 we must use Shanks-Tonelli GH #4027
This one is a little more involved since this is the first curve where p != 3 mod 4, and in fact since P-224 is == 1 mod 16 we must use Shanks-Tonelli GH #4027
This one is a little more involved since this is the first curve where p != 3 mod 4, and in fact since P-224 is == 1 mod 16 we must use Shanks-Tonelli GH #4027
This one is a little more involved since this is the first curve where p != 3 mod 4, and in fact since P-224 is == 1 mod 16 we must use Shanks-Tonelli GH #4027
This one is a little more involved since this is the first curve where p != 3 mod 4, and in fact since P-224 is == 1 mod 16 we must use Shanks-Tonelli GH #4027
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027 Co-Authored-By: René Meusel <[email protected]>
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027 Co-Authored-By: René Meusel <[email protected]>
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027 Co-Authored-By: René Meusel <[email protected]>
This is analagous to the DL scheme key types added in #3210, but here we have to retain the existing classes as we are constrained by SemVer. The new types contain both our old types (BigInt, EC_Point) and new types (EC_Scalar, EC_AffinePoint). Eventually the legacy types will be removed, but we can't do that until the next major version. GH #4027 Co-Authored-By: René Meusel <[email protected]>
This one is a little more involved since this is the first curve where p != 3 mod 4, and in fact since P-224 is == 1 mod 16 we must use Shanks-Tonelli GH #4027
This one is a little more involved since this is the first curve where p != 3 mod 4, and in fact since P-224 is == 1 mod 16 we must use Shanks-Tonelli GH randombit#4027
Hello, I am new to this library so I might be missing something, but from what I understand, you are deprecating EC_Point and replacing it with EC_AffinePoint. My concern is, that currently I dont see currently how to add two distinct EC_AffinePoints. Of course, for Diffie-Hellman all one needs is interface that takes a scalar n and calculates n*P for some point P. However, in other applications you may want to add distinct points. So my question is, is there a way to add two EC_AffinePoints? Thank you in advance. |
@Honzaik this is not currently supported simply because the interface of EC_AffinePoint was quite intentionally done as the absolute minimum required to implement the relevant algorithms. This is to a large extent a resposne to EC_Point which has a huge number of very specialized interfaces, many of which make it difficult to implement EC_Point using any other approach than exactly how it is currently implemented. In the short term the answer is if you want point addition use EC_Point - it’s deprecated but thats just an advisory that it will be removed down the line (next major release in ~~~ 2027) It’s very likely EC_AffinePoint will gain point addition. I debated adding it during the initial implemenetation and then decided to wait until it’s actually in use. That will come anway when SPAKE2 is implemented, since that requires point additions. I would be curious as to what kind of protocol you are implementing. |
@randombit thank you for the explanation. My use case is similar to SPAKE2, i.e., some PAKE-adjacent constuctions. Specifically, PAPKE (https://eprint.iacr.org/2019/199.pdf) which can be used to build PAKE requires addition of different points. Similarly, the M2F construction from https://eprint.iacr.org/2023/295.pdf also requires addition. These constructions also need hashing to curve, but that is already implemented (for prime curves), however, I'd also note that the "uniform hashing" construction (https://www.ietf.org/archive/id/draft-irtf-cfrg-hash-to-curve-16.html#section-3-4.2.2) also requires adding two points. Don't get me wrong, I am doing just a proof of concept implementation and all these use cases basically boil down to PAKEs so I understand I am a tiny minority of users that need it. At the end, I understand why a lot of crypto libraries try to minimize the opportunity for their users to shoot themselves in the foot and power users can in the end fork it and expose the hidden functions (with a little bit of work). On the other hand, I feel like leaving the addition implemented doesn't pose that much of a risk (maybe as some sort of a “hazmat” layer, like in python cryptography). |
It's not specifically about preventing users from shooting themselves in the foot. TBH working at this level -- using raw elliptic curve points to define a new protocol -- you had better know what you are doing anyway! It was more that the interface of Point addition will be added when SPAKE2 is added, or perhaps I'll just add it for 3.7.0 right away since addition plus point negation probably unblocks most of the basic protocols one might want to implement. |
This adds point negation and point addition. Point addition is not particularly efficient since it converts the result immediately to an affine coordinate, as we do not currently expose projective points at all. That said it is more than sufficient for simple protocols that just need to add a few points together. This also corrects the return result of EC_AffinePoint::mul_px_qy, which would previously crash if the resulting point was the identity element. Instead it should return nullopt. Discussion in #4027
This adds point negation and point addition. Point addition is not particularly efficient since it converts the result immediately to an affine coordinate, as we do not currently expose projective points at all. That said it is more than sufficient for simple protocols that just need to add a few points together. This also corrects the return result of EC_AffinePoint::mul_px_qy, which would previously crash if the resulting point was the identity element. Instead it should return nullopt. Discussion in #4027
Great! Thank you very much. |
Botan 3.5.0
In this release pcurves is really just used for hash to curve
BigInt
, egmod_sub
,ct_reduce_below
, many more.Support for providing parameterized curves, where we eg compute Montgomery params at runtime. This is required not just for user provided/application specific curves but also I don't think it's worthwhile to provide the fully parameterized/hardcoded support for obscure curves like secp160r1.In the short term, application curves, secp160r1, etc fall back to the currently used BigInt codeBotan 3.6.0
In this release, we tie together
EC_Scalar
/EC_AffinePoint
to pcurves so that everything goes fast 🚀EC_Scalar
andEC_AffinePoint
instead ofBigInt
/EC_Point
(In EC keys store the data as EC_Scalar / EC_AffinePoint #4203)EC_Scalar
/EC_AffinePoint
and pcurves (Bridge pcurves into the main elliptic curve arithmetic #4143)EC_Scalar
andEC_AffinePoint
types and implement algorithms using them Add EC_Scalar and EC_AffinePoint types #4042EC_Scalar
version to avoidEC_Scalar<->BigInt
conversions. (Now in Add EC_Scalar and EC_AffinePoint types #4042)Bumped to 3.7.0
Work originally planned for 3.6.0 but bumped to 3.7.0
CurveGFP_NIST
(we can just use Montgomery for everything)Botan 3.6.0 or later. Nice optimizations / cleanups but not critical
mul2_vartime
.Based on some reading and experimentation best option for parameters of our size is a wNAF with w==4 which should hit on average 80% dual 0s and requiring a table of 80 group elements.JSF or bust it seemsdbl-2004-hmv
bytes_to_words
kind of comically inefficient right nowThe text was updated successfully, but these errors were encountered: