# How can I convert a ECDSA curve specification from the SEC2 form into the form needed by Go?

I`m trying to implement ECDSA in the curve secp256k1 in Google Go.

Secp256k1 is defined by the SECG standard (SEC 2, part 2, Recommended Elliptic Curve Domain Parameters over 𝔽p, page 15) in terms of parameters p, a, b, G compressed, G uncompressed, n and h.

In Go's crypto library, the curves are defined by parameters P, N, B, Gx, Gy and BitSize. How do I convert parameters given by SECG into the ones needed by Go?

• I'm assuming you were asking this question for a Bitcoin implementation... how did you end up solving this issue (I see go's implementation wasn't compatible with bit coin) – halfbit Oct 25 '13 at 0:54
• @makerofthings7 - github.com/ThePiachu/Golang-Koblitz-elliptic-curve-DSA-library - I grabbed the original ECDSA libraries and changed the necessary curve parameters and curve equations to match the specifications. This library is for example powering Vanity Pool (vanitypool.appspot.com) and my testing suite (gobittest.appspot.com) - both produce addresses compatible with Bitcoin. I haven't tested the message signing, but I think someone else made a client using this library, so it should work. – ThePiachu Oct 25 '13 at 8:13

## 1 Answer

In the `elliptic` package of Go,

A `Curve` represents a short-form Weierstrass curve with a=-3.

So, we have curves of the form `y² = x³ - 3·x + B` (where both `x` and `y` take values in 𝔽P). `P` and `B` thus are the parameters to identify a curve, the others are only necessary for the operations on the curve elements which will be used for cryptography.

The SECG standard SEC 2 defines the secp256k1 curve as `y² = x³ + a·x + b` with a = 0, i.e. effectively `y² = x³ + b`.

These curves are not the same, independent of which b and B are selected here.

Your conversion is not possible with the `elliptic` package's `Curve` class, as it only supports some special class of curves (these with `a = -3`), while SEC 2 recommends curves from other classes (a = 0 for the `...k1` curves).

On the other hand, the curves with `...r1` in the name seem to have `a = -3`. And actually, `secp256r1` seems to be the same curve which is available in `elliptic` as `p256()`. (I didn't prove this, but at least some the hex digits of the uncompressed form of the base point in SEC 2 are the coordinates of the base point in elliptic.)

• secp256r1 is the same curve than NIST's P-256, defined in FIPS 186-3. The Go crypto library is documented to implement P-256. – Thomas Pornin Sep 20 '11 at 4:07