ac2db33732
- Create Economist SubmissionTracking package correctly: * mainArticle = full blog post content * coverLetter = 216-word SIR— letter * Links to blog post via blogPostId - Archive 'Letter to The Economist' from blog posts (it's the cover letter) - Fix date display on article cards (use published_at) - Target publication already displaying via blue badge Database changes: - Make blogPostId optional in SubmissionTracking model - Economist package ID: 68fa85ae49d4900e7f2ecd83 - Le Monde package ID: 68fa2abd2e6acd5691932150 Next: Enhanced modal with tabs, validation, export 🤖 Generated with [Claude Code](https://claude.com/claude-code) Co-Authored-By: Claude <noreply@anthropic.com>
119 lines
3.3 KiB
Python
119 lines
3.3 KiB
Python
"""
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PostScript Type 1 fonts make use of two types of encryption: charstring
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encryption and ``eexec`` encryption. Charstring encryption is used for
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the charstrings themselves, while ``eexec`` is used to encrypt larger
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sections of the font program, such as the ``Private`` and ``CharStrings``
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dictionaries. Despite the different names, the algorithm is the same,
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although ``eexec`` encryption uses a fixed initial key R=55665.
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The algorithm uses cipher feedback, meaning that the ciphertext is used
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to modify the key. Because of this, the routines in this module return
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the new key at the end of the operation.
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"""
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from fontTools.misc.textTools import bytechr, bytesjoin, byteord
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def _decryptChar(cipher, R):
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cipher = byteord(cipher)
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plain = ((cipher ^ (R >> 8))) & 0xFF
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R = ((cipher + R) * 52845 + 22719) & 0xFFFF
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return bytechr(plain), R
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def _encryptChar(plain, R):
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plain = byteord(plain)
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cipher = ((plain ^ (R >> 8))) & 0xFF
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R = ((cipher + R) * 52845 + 22719) & 0xFFFF
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return bytechr(cipher), R
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def decrypt(cipherstring, R):
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r"""
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Decrypts a string using the Type 1 encryption algorithm.
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Args:
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cipherstring: String of ciphertext.
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R: Initial key.
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Returns:
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decryptedStr: Plaintext string.
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R: Output key for subsequent decryptions.
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Examples::
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>>> testStr = b"\0\0asdadads asds\265"
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>>> decryptedStr, R = decrypt(testStr, 12321)
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>>> decryptedStr == b'0d\nh\x15\xe8\xc4\xb2\x15\x1d\x108\x1a<6\xa1'
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True
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>>> R == 36142
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True
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"""
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plainList = []
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for cipher in cipherstring:
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plain, R = _decryptChar(cipher, R)
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plainList.append(plain)
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plainstring = bytesjoin(plainList)
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return plainstring, int(R)
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def encrypt(plainstring, R):
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r"""
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Encrypts a string using the Type 1 encryption algorithm.
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Note that the algorithm as described in the Type 1 specification requires the
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plaintext to be prefixed with a number of random bytes. (For ``eexec`` the
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number of random bytes is set to 4.) This routine does *not* add the random
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prefix to its input.
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Args:
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plainstring: String of plaintext.
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R: Initial key.
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Returns:
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cipherstring: Ciphertext string.
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R: Output key for subsequent encryptions.
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Examples::
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>>> testStr = b"\0\0asdadads asds\265"
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>>> decryptedStr, R = decrypt(testStr, 12321)
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>>> decryptedStr == b'0d\nh\x15\xe8\xc4\xb2\x15\x1d\x108\x1a<6\xa1'
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True
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>>> R == 36142
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True
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>>> testStr = b'0d\nh\x15\xe8\xc4\xb2\x15\x1d\x108\x1a<6\xa1'
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>>> encryptedStr, R = encrypt(testStr, 12321)
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>>> encryptedStr == b"\0\0asdadads asds\265"
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True
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>>> R == 36142
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True
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"""
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cipherList = []
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for plain in plainstring:
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cipher, R = _encryptChar(plain, R)
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cipherList.append(cipher)
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cipherstring = bytesjoin(cipherList)
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return cipherstring, int(R)
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def hexString(s):
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import binascii
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return binascii.hexlify(s)
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def deHexString(h):
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import binascii
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h = bytesjoin(h.split())
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return binascii.unhexlify(h)
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if __name__ == "__main__":
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import sys
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import doctest
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sys.exit(doctest.testmod().failed)
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