As far as I know there is no point decompression function in the Go standard library (or the “x” packages), so you’d have to do it yourself (or find an existing implementation).

The implementation is not too difficult, although there are a couple of things to looks out for.

Basically, you need plug your `X`

value into the curve equation `Y`^{2} = X^{3} + aX + b

, and then determine which of the two roots you want using the sign bit. The tricky bit is remembering that all this needs to be done modulo the field prime of the group.

I find Go’s big integer package can be a bit odd to use sometimes, because it uses mutable values, but it does have a modular square root function which makes things a lot easier for us. The curve parameters are available in the `crypto/elliptic`

package, although you need to know the `a`

parameter is always `-3`

for these curves.

Assuming you have the compressed point as a `[]byte`

(with a leading `0x02`

or `0x03`

) in `compressed_bytes`

, the following should work. This is a pretty direct implementation of the equation, broken up with comments and lots of named variables to attempt to explain what’s going on. Have a look at the source of `CurveParams.IsOnCurve`

for a slightly more efficient (and shorter) implementation. It’s basically the same up until the modular square root.

```
compressed_bytes := //...
// Split the sign byte from the rest
sign_byte := uint(compressed_bytes[0])
x_bytes := compressed_bytes[1:]
// Convert to big Int.
x := new(big.Int).SetBytes(x_bytes)
// We use 3 a couple of times
three := big.NewInt(3)
// and we need the curve params for P256
c := elliptic.P256().Params()
// The equation is y^2 = x^3 - 3x + b
// First, x^3, mod P
x_cubed := new(big.Int).Exp(x, three, c.P)
// Next, 3x, mod P
three_X := new(big.Int).Mul(x, three)
three_X.Mod(three_X, c.P)
// x^3 - 3x ...
y_squared := new(big.Int).Sub(x_cubed, three_X)
// ... + b mod P
y_squared.Add(y_squared, c.B)
y_squared.Mod(y_squared, c.P)
// Now we need to find the square root mod P.
// This is where Go's big int library redeems itself.
y := new(big.Int).ModSqrt(y_squared, c.P)
if y == nil {
// If this happens then you're dealing with an invalid point.
// Panic, return an error, whatever you want here.
}
// Finally, check if you have the correct root by comparing
// the low bit with the low bit of the sign byte. If it’s not
// the same you want -y mod P instead of y.
if y.Bit(0) != sign_byte & 1 {
y.Neg(y)
y.Mod(y, c.P)
}
// Now your y coordinate is in y, for all your ScalarMult needs.
```