Your signature.sig file appears to be base64 encoded. Decode it like this:

```
$ base64 -d signature.sig >signature.bin
```

Let's see what we have:

```
$ hexdump -C signature.bin
00000000 24 98 70 45 e1 de bf c7 31 3a c3 4a 09 1e 6d fc |$.pE....1:.J..m.|
00000010 47 b7 59 4f 5c ee d9 1f f5 1b 86 35 a9 97 76 95 |G.YO\......5..v.|
00000020 d0 bb d3 8b f1 92 a7 b2 b6 e5 08 ee ef 12 63 97 |..............c.|
00000030 18 a1 ab 93 a3 6c 80 0e 49 66 94 21 5c ed c0 d5 |.....l..If.!\...|
00000040
```

For comparison purposes I created a new ECDSA private key based on the same curve your public key is using (P-256):

```
$ openssl genpkey -algorithm EC -pkeyopt ec_paramgen_curve:P-256 -out key.pem
```

And then signed some data using it:

```
$ echo "HELLO" > hello.txt
$ openssl dgst -sha256 -sign key.pem -out hello.sig hello.txt
$ openssl asn1parse -in hello.sig -inform DER
0:d=0 hl=2 l= 68 cons: SEQUENCE
2:d=1 hl=2 l= 32 prim: INTEGER :2C1599C7765B047A2E98E2265CF6DB91232200559909D7F97CA3E859A39AC02C
36:d=1 hl=2 l= 32 prim: INTEGER :14E748DF692A8A7A2E41F984497782FF03F970DDB6591CCC68C71704B959A480
```

So you'll note that what we have here is two integers in a sequence where each integer is exactly 32 bytes long. This corresponds to the ECDSA_SIG ASN.1 definition:

```
ECDSA-Sig-Value ::= SEQUENCE { r INTEGER, s INTEGER }
```

A raw ECDSA signature is comprised of two integers "r" and "s". OpenSSL expects them to be wrapped up inside a DER encoded representation. However, as you've already discovered what you have for the signature is not valid DER. It *is* however exactly 64 bytes long - which suggests it is comprised of 2 32 byte integers concatenated together.

For the purposes of this exercise we can use a hex editor to convert the raw r and s values into a DER format. Lets looks at a hexdump of the hello.sig file I created earlier:

```
$ hexdump -C hello.sig
00000000 30 44 02 20 2c 15 99 c7 76 5b 04 7a 2e 98 e2 26 |0D. ,...v[.z...&|
00000010 5c f6 db 91 23 22 00 55 99 09 d7 f9 7c a3 e8 59 |\...#".U....|..Y|
00000020 a3 9a c0 2c 02 20 14 e7 48 df 69 2a 8a 7a 2e 41 |...,. ..H.i*.z.A|
00000030 f9 84 49 77 82 ff 03 f9 70 dd b6 59 1c cc 68 c7 |..Iw....p..Y..h.|
00000040 17 04 b9 59 a4 80 |...Y..|
00000046
```

We start off with `30`

which tell us we have a sequence. The next byte is `44`

which is the length of the remaining data. Next is `02`

which is the tag for an integer, followed by `20`

(which equals 32 in decimal), which is the length of the integer. The next 32 bytes is the integer (the `r`

value). Then we have another `02`

byte (integer) and `20`

(length of 32) followed by the 32 bytes of the `s`

value.

So if we add the bytes `30 44 02 20`

to the front of your binary signature data, followed by the first 32 bytes of data, followed by `02 20`

followed by the next 32 byes we should get what we want...

...except unfortunately its not quite that simple. There is a complication in your `s`

value. You will note that it starts with the byte `d0`

. This byte has its most significat bit set - which in DER encoding of an integer indicates that the integer value is negative. That's not what we want. To get around this we have to add an extra `00`

byte onto the front of the `s`

value.

Doing that changes the overall length so we now have to add these bytes to the begining `30 45 02 20`

followed by the first 32 bytes from the signature data, followed by `02 21 00`

followed by the next 32 bytes of the signature data. I did this in a hex editor and came up with the following:

```
$ hexdump -C signature2.bin
00000000 30 45 02 20 24 98 70 45 e1 de bf c7 31 3a c3 4a |0E. $.pE....1:.J|
00000010 09 1e 6d fc 47 b7 59 4f 5c ee d9 1f f5 1b 86 35 |..m.G.YO\......5|
00000020 a9 97 76 95 02 21 00 d0 bb d3 8b f1 92 a7 b2 b6 |..v..!..........|
00000030 e5 08 ee ef 12 63 97 18 a1 ab 93 a3 6c 80 0e 49 |.....c......l..I|
00000040 66 94 21 5c ed c0 d5 |f.!\...|
00000047
```

Lets check that this looks sane:

```
$ openssl asn1parse -in signature2.bin -inform DER
0:d=0 hl=2 l= 69 cons: SEQUENCE
2:d=1 hl=2 l= 32 prim: INTEGER :24987045E1DEBFC7313AC34A091E6DFC47B7594F5CEED91FF51B8635A9977695
36:d=1 hl=2 l= 33 prim: INTEGER :D0BBD38BF192A7B2B6E508EEEF12639718A1AB93A36C800E496694215CEDC0D5
```

Now lets try and verify the signature:

```
$ openssl dgst -sha256 -verify pubkey.pem -signature signature2.bin hello.txt
Verification Failure
```

Darn. So near and yet so far. But at least we got rid of the ASN.1 errors. So why isn't it working? On a hunch I did this:

```
echo -n "HELLO" > hello2.txt
```

The "-n" arg to echo suppresses newlines from the output. Perhaps the newline shouldn't be included in the data to be digested for the signature. So, trying that out:

```
$ openssl dgst -sha256 -verify pubkey.pem -signature signature2.bin hello2.txt
Verified OK
```

Success!