/* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ /* * Encryption/decryption routines for CMS implementation, none of which are exported. */ #include "cmslocal.h" #include "secoid.h" #include "secitem.h" #include "pk11func.h" #include "secerr.h" #include "secpkcs5.h" /* * ------------------------------------------------------------------- * Cipher stuff. */ typedef SECStatus (*nss_cms_cipher_function) (void *, unsigned char *, unsigned int *, unsigned int, const unsigned char *, unsigned int); typedef SECStatus (*nss_cms_cipher_destroy) (void *, PRBool); #define BLOCK_SIZE 4096 struct NSSCMSCipherContextStr { void * cx; /* PK11 cipher context */ nss_cms_cipher_function doit; nss_cms_cipher_destroy destroy; PRBool encrypt; /* encrypt / decrypt switch */ int block_size; /* block & pad sizes for cipher */ int pad_size; int pending_count; /* pending data (not yet en/decrypted */ unsigned char pending_buf[BLOCK_SIZE];/* because of blocking */ }; /* * NSS_CMSCipherContext_StartDecrypt - create a cipher context to do decryption * based on the given bulk encryption key and algorithm identifier (which * may include an iv). * * XXX Once both are working, it might be nice to combine this and the * function below (for starting up encryption) into one routine, and just * have two simple cover functions which call it. */ NSSCMSCipherContext * NSS_CMSCipherContext_StartDecrypt(PK11SymKey *key, SECAlgorithmID *algid) { NSSCMSCipherContext *cc; void *ciphercx; CK_MECHANISM_TYPE cryptoMechType; PK11SlotInfo *slot; SECOidTag algtag; SECItem *param = NULL; algtag = SECOID_GetAlgorithmTag(algid); /* set param and mechanism */ if (SEC_PKCS5IsAlgorithmPBEAlg(algid)) { SECItem *pwitem; pwitem = PK11_GetSymKeyUserData(key); if (!pwitem) return NULL; cryptoMechType = PK11_GetPBECryptoMechanism(algid, ¶m, pwitem); if (cryptoMechType == CKM_INVALID_MECHANISM) { SECITEM_FreeItem(param,PR_TRUE); return NULL; } } else { cryptoMechType = PK11_AlgtagToMechanism(algtag); if ((param = PK11_ParamFromAlgid(algid)) == NULL) return NULL; } cc = (NSSCMSCipherContext *)PORT_ZAlloc(sizeof(NSSCMSCipherContext)); if (cc == NULL) { SECITEM_FreeItem(param,PR_TRUE); return NULL; } /* figure out pad and block sizes */ cc->pad_size = PK11_GetBlockSize(cryptoMechType, param); slot = PK11_GetSlotFromKey(key); cc->block_size = PK11_IsHW(slot) ? BLOCK_SIZE : cc->pad_size; PK11_FreeSlot(slot); /* create PK11 cipher context */ ciphercx = PK11_CreateContextBySymKey(cryptoMechType, CKA_DECRYPT, key, param); SECITEM_FreeItem(param, PR_TRUE); if (ciphercx == NULL) { PORT_Free (cc); return NULL; } cc->cx = ciphercx; cc->doit = (nss_cms_cipher_function) PK11_CipherOp; cc->destroy = (nss_cms_cipher_destroy) PK11_DestroyContext; cc->encrypt = PR_FALSE; cc->pending_count = 0; return cc; } /* * NSS_CMSCipherContext_StartEncrypt - create a cipher object to do encryption, * based on the given bulk encryption key and algorithm tag. Fill in the * algorithm identifier (which may include an iv) appropriately. * * XXX Once both are working, it might be nice to combine this and the * function above (for starting up decryption) into one routine, and just * have two simple cover functions which call it. */ NSSCMSCipherContext * NSS_CMSCipherContext_StartEncrypt(PLArenaPool *poolp, PK11SymKey *key, SECAlgorithmID *algid) { NSSCMSCipherContext *cc; void *ciphercx; SECStatus rv; CK_MECHANISM_TYPE cryptoMechType; PK11SlotInfo *slot; SECItem *param = NULL; PRBool needToEncodeAlgid = PR_FALSE; SECOidTag algtag = SECOID_GetAlgorithmTag(algid); /* set param and mechanism */ if (SEC_PKCS5IsAlgorithmPBEAlg(algid)) { SECItem *pwitem; pwitem = PK11_GetSymKeyUserData(key); if (!pwitem) return NULL; cryptoMechType = PK11_GetPBECryptoMechanism(algid, ¶m, pwitem); if (cryptoMechType == CKM_INVALID_MECHANISM) { SECITEM_FreeItem(param,PR_TRUE); return NULL; } } else { cryptoMechType = PK11_AlgtagToMechanism(algtag); if ((param = PK11_GenerateNewParam(cryptoMechType, key)) == NULL) return NULL; needToEncodeAlgid = PR_TRUE; } cc = (NSSCMSCipherContext *)PORT_ZAlloc(sizeof(NSSCMSCipherContext)); if (cc == NULL) { goto loser; } /* now find pad and block sizes for our mechanism */ cc->pad_size = PK11_GetBlockSize(cryptoMechType, param); slot = PK11_GetSlotFromKey(key); cc->block_size = PK11_IsHW(slot) ? BLOCK_SIZE : cc->pad_size; PK11_FreeSlot(slot); /* and here we go, creating a PK11 cipher context */ ciphercx = PK11_CreateContextBySymKey(cryptoMechType, CKA_ENCRYPT, key, param); if (ciphercx == NULL) { PORT_Free(cc); cc = NULL; goto loser; } /* * These are placed after the CreateContextBySymKey() because some * mechanisms have to generate their IVs from their card (i.e. FORTEZZA). * Don't move it from here. * XXX is that right? the purpose of this is to get the correct algid * containing the IVs etc. for encoding. this means we need to set this up * BEFORE encoding the algid in the contentInfo, right? */ if (needToEncodeAlgid) { rv = PK11_ParamToAlgid(algtag, param, poolp, algid); if(rv != SECSuccess) { PORT_Free(cc); cc = NULL; goto loser; } } cc->cx = ciphercx; cc->doit = (nss_cms_cipher_function)PK11_CipherOp; cc->destroy = (nss_cms_cipher_destroy)PK11_DestroyContext; cc->encrypt = PR_TRUE; cc->pending_count = 0; loser: SECITEM_FreeItem(param, PR_TRUE); return cc; } void NSS_CMSCipherContext_Destroy(NSSCMSCipherContext *cc) { PORT_Assert(cc != NULL); if (cc == NULL) return; (*cc->destroy)(cc->cx, PR_TRUE); PORT_Free(cc); } /* * NSS_CMSCipherContext_DecryptLength - find the output length of the next call to decrypt. * * cc - the cipher context * input_len - number of bytes used as input * final - true if this is the final chunk of data * * Result can be used to perform memory allocations. Note that the amount * is exactly accurate only when not doing a block cipher or when final * is false, otherwise it is an upper bound on the amount because until * we see the data we do not know how many padding bytes there are * (always between 1 and bsize). * * Note that this can return zero, which does not mean that the decrypt * operation can be skipped! (It simply means that there are not enough * bytes to make up an entire block; the bytes will be reserved until * there are enough to encrypt/decrypt at least one block.) However, * if zero is returned it *does* mean that no output buffer need be * passed in to the subsequent decrypt operation, as no output bytes * will be stored. */ unsigned int NSS_CMSCipherContext_DecryptLength(NSSCMSCipherContext *cc, unsigned int input_len, PRBool final) { int blocks, block_size; PORT_Assert (! cc->encrypt); block_size = cc->block_size; /* * If this is not a block cipher, then we always have the same * number of output bytes as we had input bytes. */ if (block_size == 0) return input_len; /* * On the final call, we will always use up all of the pending * bytes plus all of the input bytes, *but*, there will be padding * at the end and we cannot predict how many bytes of padding we * will end up removing. The amount given here is actually known * to be at least 1 byte too long (because we know we will have * at least 1 byte of padding), but seemed clearer/better to me. */ if (final) return cc->pending_count + input_len; /* * Okay, this amount is exactly what we will output on the * next cipher operation. We will always hang onto the last * 1 - block_size bytes for non-final operations. That is, * we will do as many complete blocks as we can *except* the * last block (complete or partial). (This is because until * we know we are at the end, we cannot know when to interpret * and removing the padding byte(s), which are guaranteed to * be there.) */ blocks = (cc->pending_count + input_len - 1) / block_size; return blocks * block_size; } /* * NSS_CMSCipherContext_EncryptLength - find the output length of the next call to encrypt. * * cc - the cipher context * input_len - number of bytes used as input * final - true if this is the final chunk of data * * Result can be used to perform memory allocations. * * Note that this can return zero, which does not mean that the encrypt * operation can be skipped! (It simply means that there are not enough * bytes to make up an entire block; the bytes will be reserved until * there are enough to encrypt/decrypt at least one block.) However, * if zero is returned it *does* mean that no output buffer need be * passed in to the subsequent encrypt operation, as no output bytes * will be stored. */ unsigned int NSS_CMSCipherContext_EncryptLength(NSSCMSCipherContext *cc, unsigned int input_len, PRBool final) { int blocks, block_size; int pad_size; PORT_Assert (cc->encrypt); block_size = cc->block_size; pad_size = cc->pad_size; /* * If this is not a block cipher, then we always have the same * number of output bytes as we had input bytes. */ if (block_size == 0) return input_len; /* * On the final call, we only send out what we need for * remaining bytes plus the padding. (There is always padding, * so even if we have an exact number of blocks as input, we * will add another full block that is just padding.) */ if (final) { if (pad_size == 0) { return cc->pending_count + input_len; } else { blocks = (cc->pending_count + input_len) / pad_size; blocks++; return blocks*pad_size; } } /* * Now, count the number of complete blocks of data we have. */ blocks = (cc->pending_count + input_len) / block_size; return blocks * block_size; } /* * NSS_CMSCipherContext_Decrypt - do the decryption * * cc - the cipher context * output - buffer for decrypted result bytes * output_len_p - number of bytes in output * max_output_len - upper bound on bytes to put into output * input - pointer to input bytes * input_len - number of input bytes * final - true if this is the final chunk of data * * Decrypts a given length of input buffer (starting at "input" and * containing "input_len" bytes), placing the decrypted bytes in * "output" and storing the output length in "*output_len_p". * "cc" is the return value from NSS_CMSCipher_StartDecrypt. * When "final" is true, this is the last of the data to be decrypted. * * This is much more complicated than it sounds when the cipher is * a block-type, meaning that the decryption function will only * operate on whole blocks. But our caller is operating stream-wise, * and can pass in any number of bytes. So we need to keep track * of block boundaries. We save excess bytes between calls in "cc". * We also need to determine which bytes are padding, and remove * them from the output. We can only do this step when we know we * have the final block of data. PKCS #7 specifies that the padding * used for a block cipher is a string of bytes, each of whose value is * the same as the length of the padding, and that all data is padded. * (Even data that starts out with an exact multiple of blocks gets * added to it another block, all of which is padding.) */ SECStatus NSS_CMSCipherContext_Decrypt(NSSCMSCipherContext *cc, unsigned char *output, unsigned int *output_len_p, unsigned int max_output_len, const unsigned char *input, unsigned int input_len, PRBool final) { int blocks, bsize, pcount, padsize; unsigned int max_needed, ifraglen, ofraglen, output_len; unsigned char *pbuf; SECStatus rv; PORT_Assert (! cc->encrypt); /* * Check that we have enough room for the output. Our caller should * already handle this; failure is really an internal error (i.e. bug). */ max_needed = NSS_CMSCipherContext_DecryptLength(cc, input_len, final); PORT_Assert (max_output_len >= max_needed); if (max_output_len < max_needed) { /* PORT_SetError (XXX); */ return SECFailure; } /* * hardware encryption does not like small decryption sizes here, so we * allow both blocking and padding. */ bsize = cc->block_size; padsize = cc->pad_size; /* * When no blocking or padding work to do, we can simply call the * cipher function and we are done. */ if (bsize == 0) { return (* cc->doit) (cc->cx, output, output_len_p, max_output_len, input, input_len); } pcount = cc->pending_count; pbuf = cc->pending_buf; output_len = 0; if (pcount) { /* * Try to fill in an entire block, starting with the bytes * we already have saved away. */ while (input_len && pcount < bsize) { pbuf[pcount++] = *input++; input_len--; } /* * If we have at most a whole block and this is not our last call, * then we are done for now. (We do not try to decrypt a lone * single block because we cannot interpret the padding bytes * until we know we are handling the very last block of all input.) */ if (input_len == 0 && !final) { cc->pending_count = pcount; if (output_len_p) *output_len_p = 0; return SECSuccess; } /* * Given the logic above, we expect to have a full block by now. * If we do not, there is something wrong, either with our own * logic or with (length of) the data given to us. */ if ((padsize != 0) && (pcount % padsize) != 0) { PORT_Assert (final); PORT_SetError (SEC_ERROR_BAD_DATA); return SECFailure; } /* * Decrypt the block. */ rv = (*cc->doit)(cc->cx, output, &ofraglen, max_output_len, pbuf, pcount); if (rv != SECSuccess) return rv; /* * For now anyway, all of our ciphers have the same number of * bytes of output as they do input. If this ever becomes untrue, * then NSS_CMSCipherContext_DecryptLength needs to be made smarter! */ PORT_Assert(ofraglen == pcount); /* * Account for the bytes now in output. */ max_output_len -= ofraglen; output_len += ofraglen; output += ofraglen; } /* * If this is our last call, we expect to have an exact number of * blocks left to be decrypted; we will decrypt them all. * * If not our last call, we always save between 1 and bsize bytes * until next time. (We must do this because we cannot be sure * that none of the decrypted bytes are padding bytes until we * have at least another whole block of data. You cannot tell by * looking -- the data could be anything -- you can only tell by * context, knowing you are looking at the last block.) We could * decrypt a whole block now but it is easier if we just treat it * the same way we treat partial block bytes. */ if (final) { if (padsize) { blocks = input_len / padsize; ifraglen = blocks * padsize; } else ifraglen = input_len; PORT_Assert (ifraglen == input_len); if (ifraglen != input_len) { PORT_SetError(SEC_ERROR_BAD_DATA); return SECFailure; } } else { blocks = (input_len - 1) / bsize; ifraglen = blocks * bsize; PORT_Assert (ifraglen < input_len); pcount = input_len - ifraglen; PORT_Memcpy (pbuf, input + ifraglen, pcount); cc->pending_count = pcount; } if (ifraglen) { rv = (* cc->doit)(cc->cx, output, &ofraglen, max_output_len, input, ifraglen); if (rv != SECSuccess) return rv; /* * For now anyway, all of our ciphers have the same number of * bytes of output as they do input. If this ever becomes untrue, * then sec_PKCS7DecryptLength needs to be made smarter! */ PORT_Assert (ifraglen == ofraglen); if (ifraglen != ofraglen) { PORT_SetError(SEC_ERROR_BAD_DATA); return SECFailure; } output_len += ofraglen; } else { ofraglen = 0; } /* * If we just did our very last block, "remove" the padding by * adjusting the output length. */ if (final && (padsize != 0)) { unsigned int padlen = *(output + ofraglen - 1); if (padlen == 0 || padlen > padsize) { PORT_SetError(SEC_ERROR_BAD_DATA); return SECFailure; } output_len -= padlen; } PORT_Assert (output_len_p != NULL || output_len == 0); if (output_len_p != NULL) *output_len_p = output_len; return SECSuccess; } /* * NSS_CMSCipherContext_Encrypt - do the encryption * * cc - the cipher context * output - buffer for decrypted result bytes * output_len_p - number of bytes in output * max_output_len - upper bound on bytes to put into output * input - pointer to input bytes * input_len - number of input bytes * final - true if this is the final chunk of data * * Encrypts a given length of input buffer (starting at "input" and * containing "input_len" bytes), placing the encrypted bytes in * "output" and storing the output length in "*output_len_p". * "cc" is the return value from NSS_CMSCipher_StartEncrypt. * When "final" is true, this is the last of the data to be encrypted. * * This is much more complicated than it sounds when the cipher is * a block-type, meaning that the encryption function will only * operate on whole blocks. But our caller is operating stream-wise, * and can pass in any number of bytes. So we need to keep track * of block boundaries. We save excess bytes between calls in "cc". * We also need to add padding bytes at the end. PKCS #7 specifies * that the padding used for a block cipher is a string of bytes, * each of whose value is the same as the length of the padding, * and that all data is padded. (Even data that starts out with * an exact multiple of blocks gets added to it another block, * all of which is padding.) * * XXX I would kind of like to combine this with the function above * which does decryption, since they have a lot in common. But the * tricky parts about padding and filling blocks would be much * harder to read that way, so I left them separate. At least for * now until it is clear that they are right. */ SECStatus NSS_CMSCipherContext_Encrypt(NSSCMSCipherContext *cc, unsigned char *output, unsigned int *output_len_p, unsigned int max_output_len, const unsigned char *input, unsigned int input_len, PRBool final) { int blocks, bsize, padlen, pcount, padsize; unsigned int max_needed, ifraglen, ofraglen, output_len; unsigned char *pbuf; SECStatus rv; PORT_Assert (cc->encrypt); /* * Check that we have enough room for the output. Our caller should * already handle this; failure is really an internal error (i.e. bug). */ max_needed = NSS_CMSCipherContext_EncryptLength (cc, input_len, final); PORT_Assert (max_output_len >= max_needed); if (max_output_len < max_needed) { /* PORT_SetError (XXX); */ return SECFailure; } bsize = cc->block_size; padsize = cc->pad_size; /* * When no blocking and padding work to do, we can simply call the * cipher function and we are done. */ if (bsize == 0) { return (*cc->doit)(cc->cx, output, output_len_p, max_output_len, input, input_len); } pcount = cc->pending_count; pbuf = cc->pending_buf; output_len = 0; if (pcount) { /* * Try to fill in an entire block, starting with the bytes * we already have saved away. */ while (input_len && pcount < bsize) { pbuf[pcount++] = *input++; input_len--; } /* * If we do not have a full block and we know we will be * called again, then we are done for now. */ if (pcount < bsize && !final) { cc->pending_count = pcount; if (output_len_p != NULL) *output_len_p = 0; return SECSuccess; } /* * If we have a whole block available, encrypt it. */ if ((padsize == 0) || (pcount % padsize) == 0) { rv = (* cc->doit) (cc->cx, output, &ofraglen, max_output_len, pbuf, pcount); if (rv != SECSuccess) return rv; /* * For now anyway, all of our ciphers have the same number of * bytes of output as they do input. If this ever becomes untrue, * then sec_PKCS7EncryptLength needs to be made smarter! */ PORT_Assert (ofraglen == pcount); /* * Account for the bytes now in output. */ max_output_len -= ofraglen; output_len += ofraglen; output += ofraglen; pcount = 0; } } if (input_len) { PORT_Assert (pcount == 0); blocks = input_len / bsize; ifraglen = blocks * bsize; if (ifraglen) { rv = (* cc->doit) (cc->cx, output, &ofraglen, max_output_len, input, ifraglen); if (rv != SECSuccess) return rv; /* * For now anyway, all of our ciphers have the same number of * bytes of output as they do input. If this ever becomes untrue, * then sec_PKCS7EncryptLength needs to be made smarter! */ PORT_Assert (ifraglen == ofraglen); max_output_len -= ofraglen; output_len += ofraglen; output += ofraglen; } pcount = input_len - ifraglen; PORT_Assert (pcount < bsize); if (pcount) PORT_Memcpy (pbuf, input + ifraglen, pcount); } if (final) { padlen = padsize - (pcount % padsize); PORT_Memset (pbuf + pcount, padlen, padlen); rv = (* cc->doit) (cc->cx, output, &ofraglen, max_output_len, pbuf, pcount+padlen); if (rv != SECSuccess) return rv; /* * For now anyway, all of our ciphers have the same number of * bytes of output as they do input. If this ever becomes untrue, * then sec_PKCS7EncryptLength needs to be made smarter! */ PORT_Assert (ofraglen == (pcount+padlen)); output_len += ofraglen; } else { cc->pending_count = pcount; } PORT_Assert (output_len_p != NULL || output_len == 0); if (output_len_p != NULL) *output_len_p = output_len; return SECSuccess; }