An ECDSA signature consists of two numbers, r and s which are numbers in the range [1..n-1] where n is the order of the curve. n is a (known) number in the range [2^(k-1)..2^k-1] where k is the key size. So the size of r and s are generally the same and sometimes somewhat smaller as the key size in bytes.

Now r and s can be encoded in multiple ways, of which two are common:

- r and s are DER encoded as two ASN.1 signed INTEGER types within an ASN.1 SEQUENCE.
- r and s are encoded as two statically sized, unsigned integers with the same size as the key size (or order)
*in octets or bytes*.

So the difference in size is just because the values r and s are encoded differently. Of course, you need to know the type of encoding before you can verify the signature.

As r and s are exactly the same independents of the encoding it is relatively simple to convert between the two versions (if you can call anything that requires generation or parsing of DER-encoded ASN.1 structures "simple").

Type 1 has been standardized in ANSI X9.62 and type 2, often called a flat encoding, is commonly used on embedded platforms or smart cards.

r and s are just very *likely* the same size as n / the key size, but in principle, they could be e.g. a number 3. The chance of that happening is abysmally small. You should, however, *not* perform any tests on the size of r and s. If either of them is more than 8 bytes smaller then you may start to scratch your head because the chance of that happening is between 1/2^63 and 1/2^64, i.e. *extremely* unlikely.

So:

- I am misunderstanding the wiki article.

No, the wiki article assumes the standardized encoding of ANSI X9.62.

- I am using python-ecdsa incorrectly

No, the python-ecdsa package just uses a different encoding and you are surprised.

- the bitcoin wiki is incorrect

No, the bitcoin wiki assumed a particular encoding chosen for their protocol.

- python-ecdsa is not implemented correctly

Definitely not; at least not with regards to the size of the signature.

Now for the implementation details; the following is in the documentation:

There are also multiple ways to represent a signature. The default `sk.sign()`

and `vk.verify()`

methods present it as a short string, for simplicity and minimal overhead. To use a different scheme, use the sk.sign(sigencode=) and vk.verify(sigdecode=) arguments. There are helper functions in the "ecdsa.util" module that can be useful here.

So try to use `sigencode=sigencode_der`

to get the format expected by the wiki article. The `util.py`

source has all the conversions you are likely to need. It uses `number_to_string`

to create statically sized numbers. This function is also known as I2OSP or Integer to Octet String primitive in PKCS#1 (RSA). Note that "strings" in the code refer to *octet strings*, also known as *byte arrays* - not text strings.