121 lines
5.6 KiB
HTML
121 lines
5.6 KiB
HTML
{% extends "konami.html" %}
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{% block title %}Network format{% endblock %}
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{% block body %}
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<h1>Network format</h1>
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<p>eAmuse packets are sent and received over HTTP (no S), with requests being in the body of <code>POST</code> requests,
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and replies being in the, well, reply.</p>
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<p>The packets are typically both encrypted and compressed. The compression format used is indicated by the
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<code>X-Compress</code> header, and valid values are
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</p>
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<ul>
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<li><code>none</code></li>
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<li><code>lz77</code></li>
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</ul>
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<details>
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<summary>Source code details</summary>
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<figure>
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<img src="./images/lz77.png">
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<figcaption><code>libavs-win32-ea3.dll:0x1000fa29</code></figcaption>
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</figure>
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</details>
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<p>Encryption is performed <b>after</b> compression, and uses RC4. RC4 is symmetric, so decryption is performed the same
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as encryption. That is, <code>packet = encrypt(compress(data))</code> and
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<code>data = decompress(decrypt(data))</code>.
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</p>
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<h2 id="keys">Encryption keys</h2>
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<p>Encryption is not performed using a single static key. Instead, each request and response has its own key that is
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generated.</p>
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<p>These keys are generated baesd on the <code>X-Eamuse-Info</code> header.</p>
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<p>Keys follow thge format <code>1-[0-9a-f]{8}-[0-9a-f]{4}</code>. This corresponds to
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<code>[version]-[seconds]-[salt]</code>. The salt is generated by a simple PRNG.
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</p>
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<details>
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<summary>The PRNG</summary>
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<pre>{% highlight "c" %}
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uint32_t PRNG_STATE = 0x41c64e6d;
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uint32_t prng() {
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int upper = (PRNG_STATE * 0x838c9cda) + 0x6072;
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PRNG_STATE = (PRNG_STATE * 0x41c64e6d + 0x3039) * 0x41c64e6d + 0x3039;
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return upper & 0x7fff0000 | PRNG_STATE >> 0xf & 0xffff;
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}
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{% endhighlight %}</pre>
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<p>This is a simple linear conguential pseudorandom number generator (what a mouthful) being stepped twice every
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call. The constants being used for the main LCPRNG are taken from glibc, along with the dropping of the "least
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random" bit. Where this implementation differs however is that the LCPRNG is stepped twice every call, and that
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a second LCPRNG is used for the upper 2 bytes.</p>
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<p>One interesting observation is that the "least random" bit, that is typically discarded by the
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<code>0x7ff...</code> mask is not actually being discarded here, as the upper two bytes of
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<code>PRNG_STATE</code>, not the lower two, are used unmasked.
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</p>
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<p>Another interseting observation is that due to the nature of LCGs, stepping it twice is no more secure than once.
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The implementation presented here is actually just a single step of
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<code>PRNG_STATE = (PRNG_STATE * 0xc2a29a69) + 0xd3dc167e</code>. Make sure to understand cryptography before
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trying to roll your own!
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</p>
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</details>
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<p>Our per-packet key is then generated using <code>md5(seconds | salt | ENC_KEY)</code>. Identifying
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<code>ENC_KEY</code> is left as an exercise for the reader, however should not be especially challenging.
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</p>
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<details>
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<summary>Source code details</summary>
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<p>The interesting stuff can be found at <code>libavs-win32-ea3.dll:0x1002a800</code>. Rather than screenshots, I've
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gone and tidied up the code somewhat to make it easier to follow. <code>eamuse_info</code> is pre-populated with
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<code>"X-Eamuse-Info: 1-"</code> by the calling function (<code>0x1000eeed</code>) after which the pointer is
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incremented to leave it right after that <code>-</code>, ready for us to <code>vsnprintf</code> into it.
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</p>
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<pre>{% highlight "c" %}
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static const char *ENC_KEY[26] = "Wait you didn't think I'd put this here, did you?";
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int xrpc_crypt(char *packet, char *xeamuse_info) {
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char md5_key[16];
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char key[32];
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// Copy the {8}-{4} hex char pairs into key as 6 bytes
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if (copy_from_hex(key, 4, xeamuse_info) == -1)
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return -1;
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if (xeamuse_info[8] != '-')
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return -1;
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if (copy_from_hex(key + 4, 2, xeamuse_info + 9) == -1)
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return -1;
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// Add our constant key after the two variable parts...
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strncpy(key + 6, ENC_KEY, 26);
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// ...MD5 it all...
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mdigest_create_local(0, key, 32, md5_key, 16);
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// ...and use that digest as the key for RC4
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arc4(packet, md5_key, 16);
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return 0;
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}
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int xrpc_key_and_crypt(char *packet, char *eamuse_info, size_t size) {
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uint64_t miliseconds = read_timer(0);
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uint32_t seconds = __aulldiv(miliseconds, 1000, 0);
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uint16_t salt = prng() & 0xffff;
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int bytes_formatted = vsnprintf(eamuse_info, size, "%08x-%04x", seconds, salt);
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if (bytes_formatted < size) {
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xrpc_crypt(packet, eamuse_info);
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}
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return bytes_formatted;
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}
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{% endhighlight %}</pre>
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<p></p>
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</details>
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<h2 id="lz77">LZ77</h2>
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<p>Packets are compressed using lzss. The compressed data structure is a repeating cycle of an 8 bit flags byte,
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followed by 8 values. Each value is either a single literal byte, if the corresponding bit in the preceeding flag is
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high, or is a two byte lookup into the window.</p>
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<p>The lookup bytes are structured as <code>pppppppp ppppllll</code> where <code>p</code> is a 12 bit index in the
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window, and <code>l</code> is a 4 bit integer that determines how many times to repeat the value located at that
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index in the window.</p>
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<p>The exact algorithm used for compression is not especially important, as long as it follows this format. One can
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feasibly perform no compression at all, and instead insert <code>0xFF</code> every 8 bytes (starting at index 0), to
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indicate that all values are literals. While obviously poor for compression, this is an easy way to test without
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first implementing a compressor.</p>
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{% endblock %} |