Using NSS to perform miscellaneous cryptographic operations

NSS Technical Note: 5


Encrypt/Decrypt

  1. Include headers
    #include "nss.h"
    #include "pk11pub.h"
  2. Make sure NSS is initialized.The simplest Init function, in case you don't need a NSS database is
    NSS_NoDB_Init(".")
  3. Choose a cipher mechanism. Note that some mechanisms (*_PAD) imply the padding is handled for you by NSS. If you choose something else, then data padding is the application's responsibility. You can find a list of cipher mechanisms in security/nss/lib/softoken/pkcs11.c - grep for CKF_EN_DE_.
    CK_MECHANISM_TYPE cipherMech = CKM_DES_CBC_PAD <big>(for example)</big>
  4. Choose a slot on which to do the operation
    PK11SlotInfo* slot = PK11_GetBestSlot(cipherMech, NULL);   OR
    PK11SlotInfo* slot = PK11_GetInternalKeySlot(); /* alwys returns internal slot, may not be optimal */
  5. Prepare the Key
  6. <big>Prepare the parameter for crypto context. IV is relevant only when using CBC mode of encryption. If not using CBC mode, just pass a NULL IV parm to PK11_ParamFromIV function
    SECItem ivItem;
    ivItem.data = /* ptr to an array of IV bytes */
    ivItem.len = /* length of the array of IV bytes */
    SECItem *SecParam = PK11_ParamFromIV(cipherMech, &ivItem);
    </big>
  7. <big>Now encrypt and decrypt using the key and parameter setup in above steps</big>
  8. <big>Repeat Step 6 any number of times. When all done with encrypt/decrypt ops, clean up</big>
    <big>PK11_FreeSymKey(SymKey);
    SECITEM_FreeItem(SecParam, PR_TRUE);
    PK11_FreeSlot(slot);
    </big>

Note: AES encryption, a fixed blocksize of 16 bytes is used. The Rijndael algorithm permits 3 blocksizes (16, 24, 32 bytes), but the AES standard requires the blocksize to be 16 bytes. The keysize can vary and these keysizes are permitted: 16, 24, 32 bytes.

You can also look at a sample program illustrating encryption


Hash / Digest

  1. Include headers
    #include "nss.h"
    #include "pk11pub.h"
  2. Make sure NSS is initialized.The simplest Init function, in case you don't need a NSS database is
    NSS_NoDB_Init(".")
  3. <big>Create Digest context</big>. Some of the digest algorithm identifiers are (without the SEC_OID_ prefix) : MD2, MD5, SHA1, SHA256, SHA384, SHA512.
    PK11Context* DigestContext = PK11_CreateDigestContext(SEC_OID_MD5);
  4. <big>Digest the data</big>
    <big>SECStatus s = PK11_DigestBegin(DigestContext);
    s = PK11_DigestOp(DigestContext, data, sizeof data);
    s = PK11_DigestFinal(DigestContext, digest, &len, sizeof digest);
    /* now, digest contains the 'digest', and len contains the length of the digest */
    </big>
  5. Clean up
    PK11_DestroyContext(DigestContext, PR_TRUE);


You can also look at a sample program illustrating this


Hash / Digest with secret key included

  1. Include headers
    #include "nss.h"
    #include "pk11pub.h"
  2. Make sure NSS is initialized.The simplest Init function, in case you don't need a NSS database is
    NSS_NoDB_Init(".")
  3. Choose a digest mechanism. You can find a list of digest mechanisms in security/nss/lib/softoken/pkcs11.c - grep for CKF_DIGEST.
    CK_MECHANISM_TYPE digestMech = CKM_MD5 <big>(for example)</big>
  4. Choose a slot on which to do the operation
    PK11SlotInfo* slot = PK11_GetBestSlot(digestMech, NULL);   OR
    PK11SlotInfo* slot = PK11_GetInternalKeySlot(); /* always returns int slot, may not be optimal */
  5. Prepare the Key
  6. <big>Prepare the parameter for crypto context. The param must be provided, but can be empty.
    SECItem param;
    param.data = 0;
    param.len = 0;
    </big>
  7. <big>Create Crypto context</big>
    PK11Context* DigestContext = PK11_CreateContextBySymKey(digestMech, CKA_DIGEST, SymKey,
                                                                                                                           &param);
  8. <big>Digest the data</big>, providing the key
    <big>SECStatus s = PK11_DigestBegin(DigestContext);
    s = PK11_DigestKey(DigestContext, SymKey);
    s = PK11_DigestOp(DigestContext, data, sizeof data);
    s = PK11_DigestFinal(DigestContext, digest, &len, sizeof digest);
    /* now, digest contains the 'digest', and len contains the length of the digest */
    </big>
  9. Clean up
    PK11_DestroyContext(DigestContext, PR_TRUE);
    PK11_FreeSymKey(SymKey);
    PK11_FreeSlot(slot);

You can also look at a sample program illustrating this


HMAC

  1. Include headers
    #include "nss.h"
    #include "pk11pub.h"
  2. Make sure NSS is initialized.The simplest Init function, in case you don't need a NSS database is
    NSS_NoDB_Init(".")
  3. Choose a  HMAC mechanism. You can find a list of HMAC mechanisms in security/nss/lib/softoken/pkcs11.c - grep for CKF_SN_VR, and choose the mechanisms that contain HMAC in the name
    CK_MECHANISM_TYPE hmacMech = CKM_MD5_HMAC; <big>(for example)</big>
  4. Choose a slot on which to do the operation
    PK11SlotInfo* slot = PK11_GetBestSlot(hmacMech, NULL);   OR
    PK11SlotInfo* slot = PK11_GetInternalKeySlot(); /* always returns int slot, may not be optimal */
  5. Prepare the Key
  6. <big>Prepare the parameter for crypto context. The param must be provided, but can be empty.
    SECItem param;
    param.type = siBuffer;
    param.data = NULL;
    param.len = 0;
    </big>
  7. <big>Create Crypto context</big>
    PK11Context* DigestContext = PK11_CreateContextBySymKey(hmacMech, CKA_SIGN,
                                                                                                                           SymKey, &param);
  8. <big>Digest the data</big>
    <big>SECStatus s = PK11_DigestBegin(DigestContext);
    s = PK11_DigestOp(DigestContext, data, sizeof data);
    s = PK11_DigestFinal(DigestContext, digest, &len, sizeof digest);
    /* now, digest contains the 'signed digest', and len contains the length of the digest */
    </big>
  9. Clean up
    PK11_DestroyContext(DigestContext, PR_TRUE);
    PK11_FreeSymKey(SymKey);
    PK11_FreeSlot(slot);


You can also look at a sample program illustrating this


Symmetric Key Wrapping/Unwrapping of a Symmetric Key

  1. Include headers
    #include "nss.h"
    #include "pk11pub.h"
  2. Make sure NSS is initialized.The simplest Init function, in case you don't need a NSS database is
    NSS_NoDB_Init(".")
  3. Choose a  Wrapping mechanism. See wrapMechanismList in security/nss/lib/pk11wrap/pk11slot.c and security/nss/lib/ssl/ssl3con.c for examples of wrapping mechanisms. Most of them are cipher mechanisms.
    CK_MECHANISM_TYPE wrapMech = CKM_DES3_ECB; <big>(for example)</big>
  4. Choose a slot on which to do the operation
    PK11SlotInfo* slot = PK11_GetBestSlot(wrapMech, NULL);   OR
    PK11SlotInfo* slot = PK11_GetInternalKeySlot(); /* always returns int slot, may not be optimal */


    <big>Regarding the choice of slot and wrapMech, if you know one, you can derive the other. You can get the best slot given a wrap mechanism (as shown above), or get the best wrap mechanism given a slot using:</big>

    CK_MECHANISM_TYPE wrapMech = PK11_GetBestWrapMechanism(slot)
  5. Prepare the Wrapping Key
  6. Prepare the To-be-Wrapped Key
  7. <big>Prepare the parameter for crypto context. IV is relevant only when using CBC cipher mode. If not using CBC mode, just pass a NULL SecParam to PK11_WrapSymKey or PK11_UnwrapSymKey function
    SECItem ivItem;
    ivItem.data = /* ptr to an array of IV bytes */
    ivItem.len = /* length of the array of IV bytes */
    SECItem *SecParam = PK11_ParamFromIV(wrapMech, &ivItem);
    </big>
  8. Allocate space for the wrapped key
    SECItem WrappedKey;
    WrappedKey.len = SOME_LEN;
    WrappedKey.data = allocate (SOME_LEN) bytes;
  9. <big>Do the Wrap</big>. Note that the WrappingSymKey and the ToBeWrappedSymKey must be on the slot where the wrap is going to happen. To move  keys to the desired slot, see section Moving a Key from one slot to another
    <big>SECStatus s = PK11_WrapSymKey(wrapMech, SecParam, WrappingSymKey,
                                                                     ToBeWrappedSymKey, &WrappedKey);
    </big>
  10. <big><big>Transport/Store or do whatever with the Wrapped Key (WrappedKey.data, WrappedKey.len)</big></big>
  11. <big><big>Unwrapping. </big></big>
  12. Clean up
    PK11_FreeSymKey(WrappingSymKey);
    PK11_FreeSymKey(ToBeWrappedSymKey);
    PK11_FreeSymKey(UnwrappedSymKey);
    if (SecParam) SECITEM_FreeItem(SecParam, PR_TRUE);

    SECITEM_FreeItem(&WrappedKey, PR_TRUE);
    PK11_FreeSlot(slot); 

Symmetric Key Wrapping/Unwrapping of a Private Key

  1. Include headers
    #include "nss.h"
    #include "pk11pub.h"
  2. Make sure NSS is initialized.
  3. Choose a  Wrapping mechanism. See wrapMechanismList in security/nss/lib/pk11wrap/pk11slot.c and security/nss/lib/ssl/ssl3con.c for examples of wrapping mechanisms. Most of them are cipher mechanisms.
    CK_MECHANISM_TYPE wrapMech = CKM_DES3_ECB; <big>(for example).</big>
  4. Slot on which to do the operation
    PK11SlotInfo* slot = PK11_GetBestSlot(wrapMech, NULL);   OR
    PK11SlotInfo* slot = PK11_GetInternalKeySlot(); /* always returns int slot, may not be optimal */

    This should be the slot that is best suited for the wrapping. This may or may not be the slot that contains the private key or the slot that contains the Symmetric key.

    <big>Regarding the choice of slot and wrapMech, if you know one, you can derive the other. You can get the best slot given a wrap mechanism (as shown above), or get the best wrap mechanism given a slot using:</big>
    CK_MECHANISM_TYPE wrapMech = PK11_GetBestWrapMechanism(slot)
  5. Prepare the Wrapping Key
  6. Prepare the To-be-Wrapped Key
  7. <big>Prepare the parameter for crypto context. IV is relevant only when using CBC cipher mode. If not using CBC mode, just pass a NULL SecParam to PK11_WrapPrivKey function
    SECItem ivItem;
    ivItem.data = /* ptr to an array of IV bytes */
    ivItem.len = /* length of the array of IV bytes */
    SECItem *SecParam = PK11_ParamFromIV(wrapMech, &ivItem);
    </big>
  8. Allocate space for the wrapped key. Note that a 2048-bit wrapped RSA private key takes up around 1200 bytes.
    SECItem WrappedKey;
    WrappedKey.len = SOME_LEN;
    WrappedKey.data = allocate (SOME_LEN) bytes;
  9. <big>Do the Wrap</big>. Note that the WrappingSymKey and the ToBeWrappedPvtKey must be on the slot where the wrap is going to happen. To move  keys to the desired slot, see section Moving a Key from one slot to another
    <big>SECStatus s = PK11_WrapPrivKey(slot, WrappingSymKey,  ToBeWrappedPvtKey, wrapMech,
                                                                     SecParam, &WrappedKey, NULL);
    </big>
  10. <big><big>Transport/Store or do whatever with the Wrapped Key (WrappedKey.data, WrappedKey.len)</big></big>
  11. <big><big>Unwrapping.</big></big>
  12. Clean up
    PK11_FreeSymKey(WrappingSymKey);
    <big>if (SecParam) SECITEM_FreeItem(SecParam, PR_TRUE);</big>
    <big>SECITEM_FreeItem(&WrappedKey, PR_TRUE);</big>
    if (pubValue)  SECITEM_FreeItem(pubValue, PR_TRUE);

    if (UnwrappedPvtKey) SECKEY_DestroyPrivateKey(UnwrappedPvtKey);
    if (ToBeWrappedPvtKey) SECKEY_DestroyPrivateKey(ToBeWrappedPvtKey);
    PK11_FreeSlot(slot);

Public Key Wrapping & Private Key Unwrapping of a Symmetric Key (PKI based key transport)

  1. Include headers
    #include "nss.h"
    #include "pk11pub.h"
  2. Make sure NSS is initialized.
  3. Choose a  Wrapping mechanism. See wrapMechanismList in security/nss/lib/pk11wrap/pk11slot.c and security/nss/lib/ssl/ssl3con.c for examples of wrapping mechanisms. Most of them are cipher mechanisms.
    CK_MECHANISM_TYPE wrapMech = CKM_DES3_ECB; <big>(for example)</big>
  4. Slot on which to do the operation
    PK11SlotInfo* slot = PK11_GetBestSlot(wrapMech, NULL);   OR
    PK11SlotInfo* slot = PK11_GetInternalKeySlot(); /* always returns int slot, may not be optimal */

    This should be the slot that is best suited for the wrapping. This may or may not be the slot that contains the public/private key or the slot that contains the Symmetric key.

    <big>Regarding the choice of slot and wrapMech, if you know one, you can derive the other. You can get the best slot given a wrap mechanism (as shown above), or get the best wrap mechanism given a slot using:</big>
    CK_MECHANISM_TYPE wrapMech = PK11_GetBestWrapMechanism(slot)
  5. Prepare the Wrapping Key
  6. Prepare the To-be-Wrapped Key
  7. Allocate space for the wrapped key
    SECItem WrappedKey;
    WrappedKey.len = SOME_LEN;
    WrappedKey.data = allocate (SOME_LEN) bytes;
  8. <big>Do the Wrap</big>. Note that the WrappingPubKey and the ToBeWrappedSymKey must be on the slot where the wrap is going to happen. To move  keys to the desired slot, see section Moving a Key from one slot to another
    <big>SECStatus s = PK11_PubWrapSymKey(wrapMech, WrappingPubKey,
                                                                            ToBeWrappedSymKey, &WrappedKey);
    </big>
  9. <big><big>Transport/Store or do whatever with the Wrapped Key (WrappedKey.data, WrappedKey.len)</big></big>
  10. <big><big>Unwrapping. </big></big>
  11. Clean up
    PK11_FreeSymKey(ToBeWrappedSymKey);
    <big>SECITEM_FreeItem(&WrappedKey, PR_TRUE);</big>
    if (WrappingPubKey) SECKEY_DestroyPublicKey(WrappingPubKey);

    if (UnwrappingPvtKey) SECKEY_DestroyPrivateKey(UnwrappingPvtKey);
    PK11_FreeSlot(slot);

Also look at a sample program that uses the above functions.


Generate a Symmetric Key

Subsequent to the operation, the symmetric key may need to be transported/stored in wrapped or raw form. You can find a list of key generation mechanisms in security/nss/lib/softoken/pkcs11.c - grep for CKF_GENERATE. For some key gen mechanisms, the keysize is in bytes, and for some it is in bits.
 

  1. <big>Choose a key generation mechanism</big>
    CK_MECHANISM_TYPE keygenMech = CKM_DES_KEY_GEN;
    (for example)
  2. <big>Generate the key</big>
    PK11SymKey* SymKey = PK11_KeyGen(slot, keygenMech, NULL, keysize, NULL);

<big>You can also see an sample program that does key generation.</big>

Extract the raw key (This should not normally be used. Better to use wrapping instead. See method1 and method2 ). 

SECStatus rv = PK11_ExtractKeyValue(SymKey);
SECItem *keydata = PK11_GetKeyData(SymKey);

Generating a persistent symmetric key

SECItem keyid;
CK_MECHANISM_TYPE cipherMech = CKM_AES_CBC_PAD;
keyid.data = /* ptr to an array of bytes representing the id of the key to be generated */;
keyid.len = /* length of the array of bytes */;
/* keysize must be 0 for fixed key-length algorithms like DES... and appropriate value
 *  for non fixed-key-length algorithms */
PK11SymKey *key = PK11_TokenKeyGen(slot, cipherMech, 0, 32 /* keysize */,
                                                                               &keyid, PR_TRUE, 0);


int keylen = PK11_GetKeyLength(key);
cipherMech = PK11_GetMechanism(key);


/* find the symmetric key in the database */
key = PK11_FindFixedKey(slot, cipherMech, &keyid, 0);


Moving a Key from one slot to another


Generate an RSA Key Pair

PK11_GenerateKeyPair<big> is the function to use</big>. See a sample program that uses this function.


<big>Sign & Verify Data</big>

SECKEYPrivateKey *pvtkey;
SECItem signature;
SECItem data;
SECStatus s = PK11_Sign(pvtkey, &signature, &data);


SECKeyPublicKey *pubkey;
SECStatus s = PK11_Verify(pubkey, &signature, &data, NULL);


Misc Useful Functions

  1. Get the best wrapping mechanism supported by a slot
    CK_MECHANISM_TYPE mech = PK11_GetBestWrapMechanism(PK11SlotInfo *slot);
  2. <big>Get the best slot for a certain mechanism</big>
    PK11SlotInfo* slot = PK11_GetBestSlot(mechanism, NULL);
  3. <big>Get the best key length for a certain mechanism on a given slot</big>
    int keylen = PK11_GetBestKeyLength(PK11SlotInfo *slot, mechanism);
  4. Get the key length of a symmetric key
    int keylen = PK11_GetKeyLength(PK11SymKey *symkey);
  5. Get the mechanism given a symmetric key
    CK_MECHANISM_TYPE mech = PK11_GetMechanism(PK11SymKey *key);