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//
// Cryptographic support functions for PDFio.
//
// Copyright © 2021-2023 by Michael R Sweet.
//
// Licensed under Apache License v2.0. See the file "LICENSE" for more
// information.
//
#include "pdfio-private.h"
#if _WIN32
# include <windows.h>
# include <bcrypt.h>
# include <sys/types.h>
# include <sys/timeb.h>
#else
# include <sys/time.h>
#endif // _WIN32
#ifdef __has_include
# if __has_include(<sys/random.h>)
# define HAVE_GETRANDOM 1
# include <sys/random.h>
# endif // __has_include(<sys/random.h>)
#endif // __has_include
//
// PDF files can use one of several methods to encrypt a PDF file. There is
// an owner password that controls/unlocks full editing/usage permissions and a
// user password that unlocks limited usage of the PDF. Permissions are set
// using bits for copy, print, etc. (see the `pdfio_permission_t` enumeration).
// Passwords can be up to 32 bytes in length, with a well-known padding string
// that is applied if the string is less than 32 bytes or there is no password.
//
// > Note: PDF encryption has several design weaknesses which limit the
// > protection offered. The V2 and V4 security handlers depend on the obsolete
// > MD5 and RC4 algorithms for key generation, and Cipher Block Chaining (CBC)
// > further weakens AES support. Enforcement of usage permissions depends on
// > the consuming software honoring them, so if the password is known or (more
// > commonly) the user password is blank, it is possible to bypass usage
// > permissions completely.
//
// PDFio supports the following:
//
// - The original 40-bit RC4 (V2+R2) encryption for reading only
// - 128-bit RC4 (V2+R3) encryption for reading and writing
// - 128-bit AES (V4+R4) encryption for reading and writing
// - TODO: 256-bit AES (V6+R6) encryption for reading and writing
//
// Common values:
//
// - "F" is the file encryption key (40 to 256 bits/5 to 32 bytes)
// - "Fid" is the file ID string (stored in PDF file, 32 bytes)
// - "O" is the owner key (stored in PDF file, 32 bytes)
// - "Opad" is the padded owner password (32 bytes)
// - "P" is the permissions integer (stored in PDF file)
// - "P4" is the permissions integer as a 32-bit little-endian value
// - "U" is the user key (stored in PDF file, 32 bytes)
// - "Upad" is the padded user password (32 bytes)
//
// V2+R2 handler:
//
// F = md5(Upad+O+P4+Fid)
// O = rc4(Upad, md5(Opad))
// (unlock with owner password)
// Upad = rc4(O, md5(Opad))
// U = rc4(md5(Upad+Fid)+0[16], F)
//
// V2+R3/V4+R4 handler:
//
// F = md5(md5(Upad+O+P4+Fid))^50
// O = rc4(Upad, md5(md5(Opad))^50)^20
// (unlock with owner password)
// Upad = rc4(O, md5(md5(Opad))^50)^20
// U = rc4(md5(Upad+Fid)+0[16], F)^20
//
// V6+R6 handler:
//
// TODO: document V6+R6 handler
//
//
// Local globals...
//
static uint8_t pdf_passpad[32] = // Padding for passwords
{
0x28, 0xbf, 0x4e, 0x5e, 0x4e, 0x75, 0x8a, 0x41,
0x64, 0x00, 0x4e, 0x56, 0xff, 0xfa, 0x01, 0x08,
0x2e, 0x2e, 0x00, 0xb6, 0xd0, 0x68, 0x3e, 0x80,
0x2f, 0x0c, 0xa9, 0xfe, 0x64, 0x53, 0x69, 0x7a
};
//
// Local functions...
//
static void decrypt_user_key(pdfio_encryption_t encryption, const uint8_t *file_key, uint8_t user_key[32]);
static void encrypt_user_key(pdfio_encryption_t encryption, const uint8_t *file_key, uint8_t user_key[32]);
static void make_file_key(pdfio_encryption_t encryption, pdfio_permission_t permissions, const unsigned char *file_id, size_t file_idlen, const uint8_t *user_pad, const uint8_t *owner_key, uint8_t file_key[16]);
static void make_owner_key(pdfio_encryption_t encryption, const uint8_t *owner_pad, const uint8_t *user_pad, uint8_t owner_key[32]);
static void make_user_key(const unsigned char *file_id, size_t file_idlen, uint8_t user_key[32]);
static void pad_password(const char *password, uint8_t pad[32]);
//
// '_pdfioCryptoLock()' - Lock a PDF file by generating the encryption object and keys.
//
bool // O - `true` on success, `false` otherwise
_pdfioCryptoLock(
pdfio_file_t *pdf, // I - PDF file
pdfio_permission_t permissions, // I - Use permissions
pdfio_encryption_t encryption, // I - Type of encryption to use
const char *owner_password, // I - Owner password, if any
const char *user_password) // I - User password, if any
{
pdfio_dict_t *dict; // Encryption dictionary
uint8_t owner_pad[32], // Padded owner password
user_pad[32], // Padded user password
*file_id; // File ID bytes
size_t file_idlen; // Length of file ID
pdfio_dict_t *cf_dict, // CF dictionary
*filter_dict; // CryptFilter dictionary
if ((dict = pdfioDictCreate(pdf)) == NULL)
{
_pdfioFileError(pdf, "Unable to create encryption dictionary.");
return (false);
}
pdfioDictSetName(dict, "Filter", "Standard");
switch (encryption)
{
case PDFIO_ENCRYPTION_RC4_128 :
case PDFIO_ENCRYPTION_AES_128 :
// Create the 128-bit encryption keys...
pad_password(user_password, user_pad);
if (!owner_password && user_password && *user_password)
{
// Generate a random owner password...
_pdfioCryptoMakeRandom(owner_pad, sizeof(owner_pad));
}
else
{
// Use supplied owner password
pad_password(owner_password, owner_pad);
}
// Compute the owner key...
make_owner_key(encryption, owner_pad, user_pad, pdf->owner_key);
pdf->owner_keylen = 32;
// Generate the encryption key
file_id = pdfioArrayGetBinary(pdf->id_array, 0, &file_idlen);
make_file_key(encryption, permissions, file_id, file_idlen, user_pad, pdf->owner_key, pdf->file_key);
pdf->file_keylen = 16;
// Generate the user key...
make_user_key(file_id, file_idlen, pdf->user_key);
encrypt_user_key(encryption, pdf->file_key, pdf->user_key);
pdf->user_keylen = 32;
// Save everything in the dictionary...
pdfioDictSetNumber(dict, "Length", 128);
pdfioDictSetBinary(dict, "O", pdf->owner_key, sizeof(pdf->owner_key));
pdfioDictSetNumber(dict, "P", (int)permissions);
pdfioDictSetNumber(dict, "R", encryption == PDFIO_ENCRYPTION_RC4_128 ? 3 : 4);
pdfioDictSetNumber(dict, "V", encryption == PDFIO_ENCRYPTION_RC4_128 ? 2 : 4);
pdfioDictSetBinary(dict, "U", pdf->user_key, sizeof(pdf->user_key));
if (encryption == PDFIO_ENCRYPTION_AES_128)
{
if ((cf_dict = pdfioDictCreate(pdf)) == NULL)
{
_pdfioFileError(pdf, "Unable to create Encryption CF dictionary.");
return (false);
}
if ((filter_dict = pdfioDictCreate(pdf)) == NULL)
{
_pdfioFileError(pdf, "Unable to create Encryption CryptFilter dictionary.");
return (false);
}
pdfioDictSetName(filter_dict, "Type", "CryptFilter");
pdfioDictSetName(filter_dict, "CFM", "AESV2");
pdfioDictSetDict(cf_dict, "PDFio", filter_dict);
pdfioDictSetDict(dict, "CF", cf_dict);
pdfioDictSetName(dict, "StmF", "PDFio");
pdfioDictSetName(dict, "StrF", "PDFio");
pdfioDictSetBoolean(dict, "EncryptMetadata", true);
}
break;
case PDFIO_ENCRYPTION_AES_256 :
// TODO: Implement AES-256 (/V 6 /R 6)
default :
_pdfioFileError(pdf, "Encryption mode %d not supported for writing.", (int)encryption);
return (false);
}
if ((pdf->encrypt_obj = pdfioFileCreateObj(pdf, dict)) == NULL)
{
_pdfioFileError(pdf, "Unable to create encryption object.");
return (false);
}
pdfioObjClose(pdf->encrypt_obj);
pdf->encryption = encryption;
pdf->permissions = permissions;
return (true);
}
//
// '_pdfioCryptoMakeRandom()' - Fill a buffer with good random numbers.
//
void
_pdfioCryptoMakeRandom(uint8_t *buffer, // I - Buffer
size_t bytes) // I - Number of bytes
{
#ifdef __APPLE__
// macOS/iOS provide the arc4random function which is seeded with entropy
// from the system...
while (bytes > 0)
{
// Just collect 8 bits from each call to fill the buffer...
*buffer++ = (uint8_t)arc4random();
bytes --;
}
#else
# if _WIN32
// Windows provides the CryptGenRandom function...
HCRYPTPROV prov; // Cryptographic provider
if (CryptAcquireContextA(&prov, NULL, NULL, PROV_RSA_FULL, 0))
{
// Got the default crypto provider, try to get random data...
BOOL success = CryptGenRandom(prov, (DWORD)bytes, buffer);
// Release the crypto provider and return on success...
CryptReleaseContext(prov, 0);
if (success)
return;
}
# elif HAVE_GETRANDOM
// Linux provides a system call called getrandom that uses system entropy ...
ssize_t rbytes; // Bytes read
while (bytes > 0)
{
if ((rbytes = getrandom(buffer, bytes, 0)) < 0)
{
if (errno != EINTR && errno != EAGAIN)
break;
}
bytes -= (size_t)rbytes;
buffer += rbytes;
}
if (bytes == 0)
return;
# else
// Other UNIX-y systems have /dev/urandom...
int fd; // Random number file
ssize_t rbytes; // Bytes read
// Fall back on /dev/urandom...
if ((fd = open("/dev/urandom", O_RDONLY)) >= 0)
{
while (bytes > 0)
{
if ((rbytes = read(fd, buffer, bytes)) < 0)
{
if (errno != EINTR && errno != EAGAIN)
break;
}
bytes -= (size_t)rbytes;
buffer += rbytes;
}
close(fd);
if (bytes == 0)
return;
}
# endif // _WIN32
// If we get here then we were unable to get enough random data or the local
// system doesn't have enough entropy. Make some up...
uint32_t i, // Looping var
mt_state[624], // Mersenne twister state
mt_index, // Mersenne twister index
temp; // Temporary value
# if _WIN32
struct _timeb curtime; // Current time
_ftime(&curtime);
mt_state[0] = (uint32_t)(curtime.time + curtime.millitm);
# else
struct timeval curtime; // Current time
gettimeofday(&curtime, NULL);
mt_state[0] = (uint32_t)(curtime.tv_sec + curtime.tv_usec);
# endif // _WIN32
// Seed the random number state...
mt_index = 0;
for (i = 1; i < 624; i ++)
mt_state[i] = (uint32_t)((1812433253 * (mt_state[i - 1] ^ (mt_state[i - 1] >> 30))) + i);
// Fill the buffer with random numbers...
while (bytes > 0)
{
if (mt_index == 0)
{
// Generate a sequence of random numbers...
uint32_t i1 = 1, i397 = 397; // Looping vars
for (i = 0; i < 624; i ++)
{
temp = (mt_state[i] & 0x80000000) + (mt_state[i1] & 0x7fffffff);
mt_state[i] = mt_state[i397] ^ (temp >> 1);
if (temp & 1)
mt_state[i] ^= 2567483615u;
i1 ++;
i397 ++;
if (i1 == 624)
i1 = 0;
if (i397 == 624)
i397 = 0;
}
}
// Pull 32-bits of random data...
temp = mt_state[mt_index ++];
temp ^= temp >> 11;
temp ^= (temp << 7) & 2636928640u;
temp ^= (temp << 15) & 4022730752u;
temp ^= temp >> 18;
if (mt_index == 624)
mt_index = 0;
// Copy to the buffer...
switch (bytes)
{
case 1 :
*buffer++ = (uint8_t)(temp >> 24);
bytes --;
break;
case 2 :
*buffer++ = (uint8_t)(temp >> 24);
*buffer++ = (uint8_t)(temp >> 16);
bytes -= 2;
break;
case 3 :
*buffer++ = (uint8_t)(temp >> 24);
*buffer++ = (uint8_t)(temp >> 16);
*buffer++ = (uint8_t)(temp >> 8);
bytes -= 3;
break;
default :
*buffer++ = (uint8_t)(temp >> 24);
*buffer++ = (uint8_t)(temp >> 16);
*buffer++ = (uint8_t)(temp >> 8);
*buffer++ = (uint8_t)temp;
bytes -= 4;
break;
}
}
#endif // __APPLE__
}
//
// '_pdfioCryptoMakeReader()' - Setup a cryptographic context and callback for reading.
//
_pdfio_crypto_cb_t // O - Decryption callback or `NULL` for none
_pdfioCryptoMakeReader(
pdfio_file_t *pdf, // I - PDF file
pdfio_obj_t *obj, // I - PDF object
_pdfio_crypto_ctx_t *ctx, // I - Pointer to crypto context
uint8_t *iv, // I - Buffer for initialization vector
size_t *ivlen) // IO - Size of initialization vector
{
uint8_t data[21]; // Key data
_pdfio_md5_t md5; // MD5 state
uint8_t digest[16]; // MD5 digest value
#if PDFIO_OBJ_CRYPT
pdfio_array_t *id_array; // Object ID array
unsigned char *id_value; // Object ID value
size_t id_len; // Length of object ID
uint8_t temp_key[16]; // File key for object
#endif // PDFIO_OBJ_CRYPT
uint8_t *file_key; // Computed file key to use
PDFIO_DEBUG("_pdfioCryptoMakeReader(pdf=%p, obj=%p(%d), ctx=%p, iv=%p, ivlen=%p(%d))\n", pdf, obj, (int)obj->number, ctx, iv, ivlen, (int)*ivlen);
// Range check input...
if (!pdf)
{
*ivlen = 0;
return (NULL);
}
#if PDFIO_OBJ_CRYPT
if ((id_array = pdfioDictGetArray(pdfioObjGetDict(obj), "ID")) != NULL)
{
// Object has its own ID that will get used for encryption...
_pdfio_md5_t md5; // MD5 context
uint8_t file_digest[16]; // MD5 digest of file ID and pad
uint8_t user_pad[32], // Padded user password
own_user_key[32], // Calculated user key
pdf_user_key[32]; // Decrypted user key
PDFIO_DEBUG("_pdfioCryptoMakeReader: Per-object file ID.\n");
if ((id_value = pdfioArrayGetBinary(id_array, 0, &id_len)) == NULL)
{
*ivlen = 0;
return (NULL);
}
_pdfioCryptoMD5Init(&md5);
_pdfioCryptoMD5Append(&md5, pdf_passpad, 32);
_pdfioCryptoMD5Append(&md5, id_value, id_len);
_pdfioCryptoMD5Finish(&md5, file_digest);
make_owner_key(pdf->encryption, pdf->password, pdf->owner_key, user_pad);
make_file_key(pdf->encryption, pdf->permissions, id_value, id_len, user_pad, pdf->owner_key, temp_key);
make_user_key(id_value, id_len, own_user_key);
if (memcmp(own_user_key, pdf->user_key, sizeof(own_user_key)))
{
PDFIO_DEBUG("_pdfioCryptoMakeReader: Not user password, trying owner password.\n");
make_file_key(pdf->encryption, pdf->permissions, id_value, id_len, pdf->password, pdf->owner_key, temp_key);
make_user_key(id_value, id_len, own_user_key);
memcpy(pdf_user_key, pdf->user_key, sizeof(pdf_user_key));
decrypt_user_key(pdf->encryption, temp_key, pdf_user_key);
if (memcmp(pdf->password, pdf_user_key, 32) && memcmp(own_user_key, pdf_user_key, 16))
{
*ivlen = 0;
return (NULL);
}
}
file_key = temp_key;
}
else
#endif // PDFIO_OBJ_CRYPT
{
// Use the default file key...
file_key = pdf->file_key;
}
switch (pdf->encryption)
{
default :
*ivlen = 0;
return (NULL);
case PDFIO_ENCRYPTION_RC4_40 :
// Copy the key data for the MD5 hash.
memcpy(data, file_key, 16);
data[16] = (uint8_t)obj->number;
data[17] = (uint8_t)(obj->number >> 8);
data[18] = (uint8_t)(obj->number >> 16);
data[19] = (uint8_t)obj->generation;
data[20] = (uint8_t)(obj->generation >> 8);
// Hash it...
_pdfioCryptoMD5Init(&md5);
_pdfioCryptoMD5Append(&md5, data, sizeof(data));
_pdfioCryptoMD5Finish(&md5, digest);
// Initialize the RC4 context using 40 bits of the digest...
_pdfioCryptoRC4Init(&ctx->rc4, digest, 5);
*ivlen = 0;
return ((_pdfio_crypto_cb_t)_pdfioCryptoRC4Crypt);
case PDFIO_ENCRYPTION_AES_128 :
if (*ivlen < 16)
{
*ivlen = 0;
_pdfioFileError(pdf, "Value too short for AES encryption.");
return (NULL);
}
case PDFIO_ENCRYPTION_RC4_128 :
// Copy the key data for the MD5 hash.
memcpy(data, file_key, 16);
data[16] = (uint8_t)obj->number;
data[17] = (uint8_t)(obj->number >> 8);
data[18] = (uint8_t)(obj->number >> 16);
data[19] = (uint8_t)obj->generation;
data[20] = (uint8_t)(obj->generation >> 8);
// Hash it...
_pdfioCryptoMD5Init(&md5);
_pdfioCryptoMD5Append(&md5, data, sizeof(data));
if (pdf->encryption == PDFIO_ENCRYPTION_AES_128)
_pdfioCryptoMD5Append(&md5, (const uint8_t *)"sAlT", 4);
_pdfioCryptoMD5Finish(&md5, digest);
// Initialize the RC4/AES context using the digest...
if (pdf->encryption == PDFIO_ENCRYPTION_RC4_128)
{
*ivlen = 0;
_pdfioCryptoRC4Init(&ctx->rc4, digest, sizeof(digest));
return ((_pdfio_crypto_cb_t)_pdfioCryptoRC4Crypt);
}
else
{
*ivlen = 16;
_pdfioCryptoAESInit(&ctx->aes, digest, sizeof(digest), iv);
return ((_pdfio_crypto_cb_t)_pdfioCryptoAESDecrypt);
}
}
}
//
// '_pdfioCryptoMakeWriter()' - Setup a cryptographic context and callback for writing.
//
_pdfio_crypto_cb_t // O - Encryption callback or `NULL` for none
_pdfioCryptoMakeWriter(
pdfio_file_t *pdf, // I - PDF file
pdfio_obj_t *obj, // I - PDF object
_pdfio_crypto_ctx_t *ctx, // I - Pointer to crypto context
uint8_t *iv, // I - Buffer for initialization vector
size_t *ivlen) // IO - Size of initialization vector
{
uint8_t data[21]; /* Key data */
_pdfio_md5_t md5; /* MD5 state */
uint8_t digest[16]; /* MD5 digest value */
PDFIO_DEBUG("_pdfioCryptoMakeWriter(pdf=%p, obj=%p(%d), ctx=%p, iv=%p, ivlen=%p(%d))\n", pdf, obj, (int)obj->number, ctx, iv, ivlen, (int)*ivlen);
// Range check input...
if (!pdf)
{
*ivlen = 0;
return (NULL);
}
switch (pdf->encryption)
{
default :
*ivlen = 0;
return (NULL);
case PDFIO_ENCRYPTION_RC4_128 :
case PDFIO_ENCRYPTION_AES_128 :
// Copy the key data for the MD5 hash.
memcpy(data, pdf->file_key, sizeof(pdf->file_key));
data[16] = (uint8_t)obj->number;
data[17] = (uint8_t)(obj->number >> 8);
data[18] = (uint8_t)(obj->number >> 16);
data[19] = (uint8_t)obj->generation;
data[20] = (uint8_t)(obj->generation >> 8);
// Hash it...
_pdfioCryptoMD5Init(&md5);
_pdfioCryptoMD5Append(&md5, data, sizeof(data));
if (pdf->encryption == PDFIO_ENCRYPTION_AES_128)
_pdfioCryptoMD5Append(&md5, (const uint8_t *)"sAlT", 4);
_pdfioCryptoMD5Finish(&md5, digest);
// Initialize the RC4/AES context using the digest...
if (pdf->encryption == PDFIO_ENCRYPTION_RC4_128)
{
*ivlen = 0;
_pdfioCryptoRC4Init(&ctx->rc4, digest, sizeof(digest));
return ((_pdfio_crypto_cb_t)_pdfioCryptoRC4Crypt);
}
else
{
*ivlen = 16;
_pdfioCryptoMakeRandom(iv, *ivlen);
_pdfioCryptoAESInit(&ctx->aes, digest, sizeof(digest), iv);
return ((_pdfio_crypto_cb_t)_pdfioCryptoAESEncrypt);
}
}
}
//
// '_pdfioCryptoUnlock()' - Unlock an encrypted PDF.
//
bool // O - `true` on success, `false` otherwise
_pdfioCryptoUnlock(
pdfio_file_t *pdf, // I - PDF file
pdfio_password_cb_t password_cb, // I - Password callback or `NULL` for none
void *password_data) // I - Password callback data, if any
{
int tries; // Number of tries
const char *password = NULL; // Password to try
pdfio_dict_t *encrypt_dict; // Encrypt objection dictionary
int version, // Version value
revision, // Revision value
length; // Key length value
const char *handler, // Security handler name
*stream_filter, // Stream encryption filter
*string_filter; // String encryption filter
pdfio_dict_t *cf_dict; // CryptFilters dictionary
unsigned char *owner_key, // Owner key
*user_key, // User key
*file_id; // File ID value
size_t owner_keylen, // Length of owner key
user_keylen, // Length of user key
file_idlen; // Length of file ID
_pdfio_md5_t md5; // MD5 context
uint8_t file_digest[16]; // MD5 digest of file ID and pad
// See if we support the type of encryption specified by the Encrypt object
// dictionary...
if ((encrypt_dict = pdfioObjGetDict(pdf->encrypt_obj)) == NULL)
{
_pdfioFileError(pdf, "Unable to get encryption dictionary.");
return (false);
}
handler = pdfioDictGetName(encrypt_dict, "Filter");
version = (int)pdfioDictGetNumber(encrypt_dict, "V");
revision = (int)pdfioDictGetNumber(encrypt_dict, "R");
length = (int)pdfioDictGetNumber(encrypt_dict, "Length");
PDFIO_DEBUG("_pdfioCryptoUnlock: handler=%p(%s), version=%d, revision=%d, length=%d\n", (void *)handler, handler ? handler : "(null)", version, revision, length);
if (!handler || strcmp(handler, "Standard"))
{
_pdfioFileError(pdf, "Unsupported security handler '%s'.", handler ? handler : "(null)");
return (false);
}
if (version == 4 && revision == 4)
{
// Lookup crypt filter to see if we support it...
pdfio_dict_t *filter; // Crypt Filter
const char *cfm; // Crypt filter method
stream_filter = pdfioDictGetName(encrypt_dict, "StmF");
string_filter = pdfioDictGetName(encrypt_dict, "StrF");
cf_dict = pdfioDictGetDict(encrypt_dict, "CF");
if (!cf_dict)
{
_pdfioFileError(pdf, "Missing encryption filter dictionary.");
return (false);
}
else if (!stream_filter)
{
_pdfioFileError(pdf, "Missing stream encryption filter.");
return (false);
}
else if (!string_filter)
{
_pdfioFileError(pdf, "Missing string encryption filter.");
return (false);
}
else if (strcmp(stream_filter, string_filter))
{
_pdfioFileError(pdf, "Different stream and string encryption filters - not supported.");
return (false);
}
else if ((filter = pdfioDictGetDict(cf_dict, stream_filter)) == NULL)
{
_pdfioFileError(pdf, "Missing stream encryption filter '%s'.", stream_filter);
return (false);
}
else if ((cfm = pdfioDictGetName(filter, "CFM")) == NULL)
{
_pdfioFileError(pdf, "Missing encryption filter method.");
return (false);
}
else
{
PDFIO_DEBUG("_pdfioCryptoUnlock: CFM=\"%s\"\n", cfm);
if (length < 40 || length > 128)
length = 128; // Default to 128 bits
if (!strcmp(cfm, "V2"))
pdf->encryption = PDFIO_ENCRYPTION_RC4_128;
else if (!strcmp(cfm, "AESV2"))
pdf->encryption = PDFIO_ENCRYPTION_AES_128;
}
}
else if (version == 1 || version == 2)
{
if (revision == 2)
{
pdf->encryption = PDFIO_ENCRYPTION_RC4_40;
length = 40;
}
else if (revision == 3)
{
pdf->encryption = PDFIO_ENCRYPTION_RC4_128;
if (length < 40 || length > 128)
length = 128;
}
}
else if (version == 6 && revision == 6)
{
// TODO: Implement AES-256 - V6 R6
pdf->encryption = PDFIO_ENCRYPTION_AES_256;
length = 256;
}
PDFIO_DEBUG("_pdfioCryptoUnlock: encryption=%d, length=%d\n", pdf->encryption, length);
if (pdf->encryption == PDFIO_ENCRYPTION_NONE)
{
_pdfioFileError(pdf, "Unsupported encryption V%d R%d.", version, revision);
return (false);
}
// Grab the remaining values we need to unlock the PDF...
pdf->file_keylen = (size_t)(length / 8);
pdf->permissions = (pdfio_permission_t)pdfioDictGetNumber(encrypt_dict, "P");
PDFIO_DEBUG("_pdfioCryptoUnlock: permissions=%d\n", pdf->permissions);
owner_key = pdfioDictGetBinary(encrypt_dict, "O", &owner_keylen);
user_key = pdfioDictGetBinary(encrypt_dict, "U", &user_keylen);
if (!owner_key)
{
_pdfioFileError(pdf, "Missing owner key, unable to unlock file.");
return (false);
}
else if (owner_keylen < 32 || owner_keylen > sizeof(pdf->owner_key))
{
_pdfioFileError(pdf, "Bad %d bytes owner key, unable to unlock file.", (int)owner_keylen);
return (false);
}
PDFIO_DEBUG("_pdfioCryptoUnlock: owner_key[%d]=%02X%02X%02X%02X...%02X%02X%02X%02X\n", (int)owner_keylen, owner_key[0], owner_key[1], owner_key[2], owner_key[3], owner_key[28], owner_key[29], owner_key[30], owner_key[31]);
memcpy(pdf->owner_key, owner_key, owner_keylen);
pdf->owner_keylen = owner_keylen;
if (!user_key)
{
_pdfioFileError(pdf, "Missing user key, unable to unlock file.");
return (false);
}
else if (user_keylen < 32 || user_keylen > sizeof(pdf->user_key))
{
_pdfioFileError(pdf, "Bad %d byte user key, unable to unlock file.", (int)user_keylen);
return (false);
}
PDFIO_DEBUG("_pdfioCryptoUnlock: user_key[%d]=%02X%02X%02X%02X...%02X%02X%02X%02X\n", (int)user_keylen, user_key[0], user_key[1], user_key[2], user_key[3], user_key[28], user_key[29], user_key[30], user_key[31]);
memcpy(pdf->user_key, user_key, user_keylen);
pdf->user_keylen = user_keylen;
if ((file_id = pdfioArrayGetBinary(pdf->id_array, 0, &file_idlen)) == NULL || file_idlen < 16)
{
_pdfioFileError(pdf, "Missing or bad file ID, unable to unlock file.");
return (false);
}
// Generate a base hash from known values...
_pdfioCryptoMD5Init(&md5);
_pdfioCryptoMD5Append(&md5, pdf_passpad, 32);
_pdfioCryptoMD5Append(&md5, file_id, file_idlen);
_pdfioCryptoMD5Finish(&md5, file_digest);
// Now try to unlock the PDF...
for (tries = 0; tries < 4; tries ++)
{
if (pdf->encryption <= PDFIO_ENCRYPTION_AES_128)
{
uint8_t pad[32], // Padded password
file_key[16], // File key
user_pad[32], // Padded user password
own_user_key[32], // Calculated user key
pdf_user_key[32]; // Decrypted user key
// Pad the supplied password, if any...
pad_password(password, pad);
// Generate keys to see if things match...
PDFIO_DEBUG("_pdfioCryptoUnlock: Trying %02X%02X%02X%02X...%02X%02X%02X%02X\n", pad[0], pad[1], pad[2], pad[3], pad[28], pad[29], pad[30], pad[31]);
PDFIO_DEBUG("_pdfioCryptoUnlock: P=%d\n", pdf->permissions);
PDFIO_DEBUG("_pdfioCryptoUnlock: Fid(%d)=%02X%02X%02X%02X...%02X%02X%02X%02X\n", (int)file_idlen, file_id[0], file_id[1], file_id[2], file_id[3], file_id[12], file_id[13], file_id[14], file_id[15]);
make_owner_key(pdf->encryption, pad, pdf->owner_key, user_pad);
PDFIO_DEBUG("_pdfioCryptoUnlock: Upad=%02X%02X%02X%02X...%02X%02X%02X%02X\n", user_pad[0], user_pad[1], user_pad[2], user_pad[3], user_pad[28], user_pad[29], user_pad[30], user_pad[31]);
make_file_key(pdf->encryption, pdf->permissions, file_id, file_idlen, user_pad, pdf->owner_key, file_key);
PDFIO_DEBUG("_pdfioCryptoUnlock: Fown=%02X%02X%02X%02X...%02X%02X%02X%02X\n", file_key[0], file_key[1], file_key[2], file_key[3], file_key[12], file_key[13], file_key[14], file_key[15]);
make_user_key(file_id, file_idlen, own_user_key);
PDFIO_DEBUG("_pdfioCryptoUnlock: U=%02X%02X%02X%02X...%02X%02X%02X%02X\n", pdf->user_key[0], pdf->user_key[1], pdf->user_key[2], pdf->user_key[3], pdf->user_key[28], pdf->user_key[29], pdf->user_key[30], pdf->user_key[31]);
PDFIO_DEBUG("_pdfioCryptoUnlock: Uown=%02X%02X%02X%02X...%02X%02X%02X%02X\n", own_user_key[0], own_user_key[1], own_user_key[2], own_user_key[3], own_user_key[28], own_user_key[29], own_user_key[30], own_user_key[31]);
if (!memcmp(own_user_key, pdf->user_key, sizeof(own_user_key)))
{
// Matches!
memcpy(pdf->file_key, file_key, sizeof(pdf->file_key));
memcpy(pdf->password, pad, sizeof(pdf->password));
return (true);
}
// Not the owner password, try the user password...
make_file_key(pdf->encryption, pdf->permissions, file_id, file_idlen, pad, pdf->owner_key, file_key);
PDFIO_DEBUG("_pdfioCryptoUnlock: Fuse=%02X%02X%02X%02X...%02X%02X%02X%02X\n", file_key[0], file_key[1], file_key[2], file_key[3], file_key[12], file_key[13], file_key[14], file_key[15]);
make_user_key(file_id, file_idlen, own_user_key);
memcpy(pdf_user_key, pdf->user_key, sizeof(pdf_user_key));
decrypt_user_key(pdf->encryption, file_key, pdf_user_key);
PDFIO_DEBUG("_pdfioCryptoUnlock: Uuse=%02X%02X%02X%02X...%02X%02X%02X%02X\n", user_key[0], user_key[1], user_key[2], user_key[3], user_key[28], user_key[29], user_key[30], user_key[31]);
PDFIO_DEBUG("_pdfioCryptoUnlock: Updf=%02X%02X%02X%02X...%02X%02X%02X%02X\n", pdf_user_key[0], pdf_user_key[1], pdf_user_key[2], pdf_user_key[3], pdf_user_key[28], pdf_user_key[29], pdf_user_key[30], pdf_user_key[31]);
if (!memcmp(pad, pdf_user_key, 32) || !memcmp(own_user_key, pdf_user_key, 16))
{
// Matches!
memcpy(pdf->file_key, file_key, sizeof(pdf->file_key));
memcpy(pdf->password, pad, sizeof(pdf->password));
return (true);
}
}
else
{
// TODO: Implement AES-256 security handler
_pdfioFileError(pdf, "Unable to unlock AES-256 encrypted file at this time.");
return (false);
}
// If we get here we need to try another password...
if (password_cb)
password = (password_cb)(password_data, pdf->filename);
if (!password)
break;
}
_pdfioFileError(pdf, "Unable to unlock PDF file.");
return (false);
}
//
// 'decrypt_user_key()' - Decrypt the user key.
//
static void
decrypt_user_key(
pdfio_encryption_t encryption, // I - Type of encryption
const uint8_t *file_key, // I - File encryption key
uint8_t user_key[32]) // IO - User key
{
size_t i, j; // Looping vars
_pdfio_rc4_t rc4; // RC4 encryption context
if (encryption == PDFIO_ENCRYPTION_RC4_40)
{
// Encrypt the result once...
_pdfioCryptoRC4Init(&rc4, file_key, 5);
_pdfioCryptoRC4Crypt(&rc4, user_key, user_key, 32);
}
else
{
// Encrypt the result 20 times...
uint8_t key[16]; // Current encryption key
for (i = 19; i > 0; i --)
{
// XOR each byte in the key with the loop counter...
for (j = 0; j < 16; j ++)
key[j] = (uint8_t)(file_key[j] ^ i);
_pdfioCryptoRC4Init(&rc4, key, 16);
_pdfioCryptoRC4Crypt(&rc4, user_key, user_key, 32);
}
_pdfioCryptoRC4Init(&rc4, file_key, 16);
_pdfioCryptoRC4Crypt(&rc4, user_key, user_key, 32);
}
}
//
// 'encrypt_user_key()' - Encrypt the user key.
//
static void
encrypt_user_key(
pdfio_encryption_t encryption, // I - Type of encryption
const uint8_t *file_key, // I - File encryption key
uint8_t user_key[32]) // IO - User key
{
size_t i, j; // Looping vars
_pdfio_rc4_t rc4; // RC4 encryption context
if (encryption == PDFIO_ENCRYPTION_RC4_40)
{
// Encrypt the result once...
_pdfioCryptoRC4Init(&rc4, file_key, 5);
_pdfioCryptoRC4Crypt(&rc4, user_key, user_key, 32);
}
else
{
// Encrypt the result 20 times...
uint8_t key[16]; // Current encryption key
for (i = 0; i < 20; i ++)
{
// XOR each byte in the key with the loop counter...
for (j = 0; j < 16; j ++)
key[j] = (uint8_t)(file_key[j] ^ i);
_pdfioCryptoRC4Init(&rc4, key, 16);
_pdfioCryptoRC4Crypt(&rc4, user_key, user_key, 32);
}
}
}
//
// 'make_file_key()' - Make the file encryption key.
//
static void
make_file_key(
pdfio_encryption_t encryption, // I - Type of encryption
pdfio_permission_t permissions, // I - File permissions
const unsigned char *file_id, // I - File ID value
size_t file_idlen, // I - Length of file ID
const uint8_t *user_pad, // I - Padded user password
const uint8_t *owner_key, // I - Owner key
uint8_t file_key[16]) // O - Encryption key
{
size_t i; // Looping var
uint8_t perm_bytes[4]; // Permissions bytes
_pdfio_md5_t md5; // MD5 context
uint8_t digest[16]; // 128-bit MD5 digest
perm_bytes[0] = (uint8_t)permissions;
perm_bytes[1] = (uint8_t)(permissions >> 8);
perm_bytes[2] = (uint8_t)(permissions >> 16);
perm_bytes[3] = (uint8_t)(permissions >> 24);
_pdfioCryptoMD5Init(&md5);
_pdfioCryptoMD5Append(&md5, user_pad, 32);
_pdfioCryptoMD5Append(&md5, owner_key, 32);
_pdfioCryptoMD5Append(&md5, perm_bytes, 4);
_pdfioCryptoMD5Append(&md5, file_id, file_idlen);
_pdfioCryptoMD5Finish(&md5, digest);
if (encryption != PDFIO_ENCRYPTION_RC4_40)
{
// MD5 the result 50 times..
for (i = 0; i < 50; i ++)
{
_pdfioCryptoMD5Init(&md5);
_pdfioCryptoMD5Append(&md5, digest, 16);
_pdfioCryptoMD5Finish(&md5, digest);
}
}
memcpy(file_key, digest, 16);
}
//
// 'make_owner_key()' - Generate the (encrypted) owner key...
//
static void
make_owner_key(
pdfio_encryption_t encryption, // I - Type of encryption
const uint8_t *owner_pad, // I - Padded owner password
const uint8_t *user_pad, // I - Padded user password
uint8_t owner_key[32]) // O - Owner key value
{
size_t i, j; // Looping vars
_pdfio_md5_t md5; // MD5 context
uint8_t digest[16]; // 128-bit MD5 digest
_pdfio_rc4_t rc4; // RC4 encryption context
// Hash the owner password...
_pdfioCryptoMD5Init(&md5);
_pdfioCryptoMD5Append(&md5, owner_pad, 32);
_pdfioCryptoMD5Finish(&md5, digest);
if (encryption != PDFIO_ENCRYPTION_RC4_40)
{
for (i = 0; i < 50; i ++)
{
_pdfioCryptoMD5Init(&md5);
_pdfioCryptoMD5Append(&md5, digest, 16);
_pdfioCryptoMD5Finish(&md5, digest);
}
}
// Copy and encrypt the padded user password...
memcpy(owner_key, user_pad, 32);
if (encryption == PDFIO_ENCRYPTION_RC4_40)
{
// Encrypt once...
_pdfioCryptoRC4Init(&rc4, digest, 5);
_pdfioCryptoRC4Crypt(&rc4, owner_key, owner_key, 32);
}
else
{
// Encrypt 20 times...
uint8_t encrypt_key[16]; // RC4 encryption key
for (i = 0; i < 20; i ++)
{
// XOR each byte in the digest with the loop counter to make a key...
for (j = 0; j < sizeof(encrypt_key); j ++)
encrypt_key[j] = (uint8_t)(digest[j] ^ i);
_pdfioCryptoRC4Init(&rc4, encrypt_key, sizeof(encrypt_key));
_pdfioCryptoRC4Crypt(&rc4, owner_key, owner_key, 32);
}
}
}
//
// 'make_user_key()' - Make the user key.
//
static void
make_user_key(
const unsigned char *file_id, // I - File ID value
size_t file_idlen, // I - Length of file ID
uint8_t user_key[32]) // O - User key
{
_pdfio_md5_t md5; // MD5 context
// Generate a base hash from known values...
_pdfioCryptoMD5Init(&md5);
_pdfioCryptoMD5Append(&md5, pdf_passpad, 32);
_pdfioCryptoMD5Append(&md5, file_id, file_idlen);
_pdfioCryptoMD5Finish(&md5, user_key);
memset(user_key + 16, 0, 16);
}
//
// 'pad_password()' - Generate a padded password.
//
static void
pad_password(const char *password, // I - Password string or `NULL`
uint8_t pad[32]) // O - Padded password
{
size_t len; // Length of password
if (password)
{
// Use the specified password
if ((len = strlen(password)) > 32)
len = 32;
}
else
{
// No password
len = 0;
}
if (len > 0)
memcpy(pad, password, len);
if (len < 32)
memcpy(pad + len, pdf_passpad, 32 - len);
}
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