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 𝔽_{P}). `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.)